DE3309993A1 - Optoelectronic end-of-tape deactivating circuit - Google Patents

Abstract

The invention relates to an optoelectronic end-of-tape deactivating circuit for a video, audio or data recording and/or reproducing apparatus. Due to differences in reflection of the automatic stop foils and of the tape of the recording media used in these apparatuses, as well as due to tolerances of the optical components used, an adjustment of the said circuit arrangement is necessary. According to the invention, this adjustment is performed automatically by a microcomputer and continuously monitored. In the case of such a controlled end-of-tape deactivating circuit, on the one hand a clear distinction between the recording medium and the automatic stop foils attached at the ends of the tape is possible and on the other hand a reliable response of the end deactivation when the automatic stop foils run into the scanning area of the optical circuit arrangement is ensured.

Description

OPTOELECTRONIC BAND END SWITCHING DESCRIPTION The invention relates to an optoelectronic tape limit switch for a video, audio or data recording and / or playback device specified in the preamble of claim 1 or 5 Art.

A known arrangement for scanning reflective marks on moving recording media works with two closely spaced photodiodes, a differential voltage is formed from their output signal voltages. The other This differential voltage is evaluated using a downstream Schmitt trigger, whose switch-on or switch-off threshold value is suitably set and adjusted can be (DE-PS 22 37 811).

Furthermore, there is an arrangement for optoelectronic end-of-line shutdown known, which essentially consists of two phototransistors connected in series for the detection of the switching foils attached at the beginning and at the end of the recording medium, a downstream comparator circuit and a microcomputer for evaluation the comparator output signals exist. The adjustment of the switching thresholds, which symmetrical to one of the reflective properties of the recording medium and the tolerances of the phototransistors should be dependent open-circuit voltage, takes place manually with the help of a trimming resistor (Grundig Technical Information 1980, Booklet 3, page 126, and Grundig Technical Information 1981S booklet 3, page 136).

The disadvantage of the known circuit arrangements lies in the above manual adjustment of the respective threshold value switch. This comparison is necessary on the one hand to avoid possible asymmetries of the switching voltages with regard to the open-circuit voltage, caused by tolerances in the electrical and optical properties of the used optocoupler to compensate and on the other hand to prevent 7 tripped due to differences in reflection with different tape material, which are either purely material-specific Type or age-related, the threshold values are exceeded and thus the tape transport is undesirably interrupted.

The invention is based on the object of an optoelectronic End-of-line shutdown in the generic term of claim 1 or 5 specified Kind of measures are to be provided through which the adjustment of the switching thresholds with regard to the tolerances of the optical components and the reflective properties of the strip material takes place automatically and is optimized, and manual comparison can be omitted.

This task is carried out by the characterizing part of the claim 1, 3 or 5 specified features solved.

Advantageous further developments of the invention emerge from the subclaims.

Embodiments of the invention are shown below with reference to drawings explained in more detail. They show: FIG. 1 an optoelectronic end-of-line switch-off two optocouplers and a digital-to-analog converter for automatic adjustment the switching thresholds, Fig. 2 an optoelectronic end-of-line shutdown with two optocouplers and two digital-to-analog converters for automatic adjustment of the switching thresholds, 3 shows an optoelectronic tape limit switch with an optocoupler and a digital-to-analog converter for automatic adjustment of the switching threshold.

In the circuit according to FIG. 1, a light-emitting diode 1 'is connected via a resistor 19 connected to the positive pole of a voltage source 20. The cathode of the Light emitting diode 1 'is connected to the anode of a second light emitting diode 2', the cathode of which is at the negative pole of the voltage source 20. Be used as photoelectric receivers two phototransistors 1, 2 are used, one of which is the collector of the phototransistor 1 to the positive pole and the emitter of the phototransistor 2 to the negative pole of the Voltage source 20 leads. The emitter of the phototransistor 1 is connected to the collector of the phototransistor 2 placed. At this connection point the series-connected Phototransistors 1, 2 are the inverting input of a non-negative feedback Operational amplifier 3 and the non-inverting input of a non-negative feedback Operational amplifier 4 connected. Both op amps have because of the in the absence of negative feedback, the function of a comparator (threshold switch). Between the non-inverting input of the operational amplifier 3 and the inverting one A resistor 7 is located at the input of the operational amplifier 4 the inverting input of the operational amplifier 4 via a resistor 8 on negative pole of the voltage source 20. The outputs of the two comparators 3, 4 lead to a microcomputer 5, which takes over the signal evaluation. For controlling A digital-to-analog converter is used to automatically adjust the switching thresholds 11 connected with the digital input 13 to a control output 14 of the microcomputer 5.

The analog output 12 of the digital-to-analog converter ii leads through a Resistor 6 to the non-inverting input of operational amplifier 3.

With such a circuit arrangement, it is possible to use an automatic and optimal adjustment of the switching thresholds in an optoelectronic end-of-line shutdown to be carried out in such a way that this ensures reliable detection of the beginning and end of the tape is achieved. The distinction between the beginning and the end of the tape is done with help of the two optocouplers 1 ', 1 and 2', 2, which are mounted in the recording device are that one is the upper half and the other is the lower half of the record carrier scans. The reflective foils at the beginning and at the end of the tape are each on the upper resp.

attached to the lower half of the band. In the idle state of the circuit arrangement neither of the two reflective foils is in the scanning range of the optocoupler and a quiescent current flows in the collector-emitter branches of the phototransistors 1, 2. Consequently lies at the connection point of the two phototransistors and thus at the inverting one Input of comparator 3 and at the non-inverting input of comparator 4 a rest voltage UO. This essentially depends on the reflection properties of the tape and the optoelectronic properties of the two optocouplers (tolerances) away. The lower switching threshold U2 and the upper switching threshold U1 should now be symmetrical to the open-circuit voltage UO in order to avoid undesired switching of the comparators in the middle of the band to prevent, or a reliable response of the comparators at the beginning and end of the tape to enable what is not guaranteed if one of the switching thresholds is very high is close to UO while the other is too far from UO. For the automatic Adjustment each time a new tape is inserted into the recording device takes place, but can also be checked during recording or playback operation the digital-to-analog converter 11 in connection with the microcomputer 5. For this purpose, the microcomputer generates via the digital-to-analog converter ii at the analog output 12 a variable, for example increasing reference voltage UR. Via the voltage divider 6, 7, 8 are the switching thresholds U1 and U2 at the inputs 9, 10 of the comparators 3, 4 varies. Reaches or exceeds the switching threshold during this calibration process U the quiescent voltage UO, then the comparator 3 switches its one logic value assigned output level from ~ Low "to" High ". This is done by the microcomputer 5 registered and the reference voltage UR present at the time of switchover becomes digital saved. With the help of the well-known resistor network 6,7,8 determines the Microcomputers 5 then the open-circuit voltage UO and the reference voltage UR, which are to be applied to the resistor 6 so that the switching thresholds U1 and U2 are symmetrical to the idle voltage UO. This determined value is stored digitally and via the analog output 12 of the digital-to-analog converter 11 to the resistor network 6, 7, 8. In order to an optimal automatic adjustment of the switching thresholds is guaranteed. Runs now the beginning or the end of the tape with the reflective layer in the Scanning range of the corresponding optocoupler, then exceeds or falls below the Voltage UO at the inverting input of the comparator 3 or at the non-inverting input Input of the comparator 4 the switching threshold U1 or U2. The corresponding comparator its output level assigned to a logical value from "High" to "lot" and gives the associated control command for shutdown the tape transport and to indicate whether it is the beginning or the end of the tape acts on to the microcomputer. After the final switch-off, it runs, controlled by the microcomputer, the tape backwards or forwards so far that the switching membrane is the beginning or the end of the tape is no longer in the scanning range of the corresponding Optocoupler is located. This ensures that even when you insert it again of the tape in the recording device the switching thresholds with respect to the open-circuit voltage UO must be set correctly, since the automatic adjustment is only carried out and to be controlled allowed if the switching foils are outside the scanning range the optocoupler lie. Otherwise a wrong setting would result.

Fig. 2 shows a further embodiment of the invention. It makes a difference differs from the first embodiment by the omission of the voltage divider 6, 7, 8 and by using another digital-to-analog converter 15. The analog output 12 of the digital-to-analog converter i1 is directly on in this circuit arrangement connected to the non-inverting input of the comparator 3. Between one second output 18 of the microcomputer 5 and the inverting input of the comparator 4 is the second digital-to-analog converter 15.

The two switching thresholds are thus not as in the first exemplary embodiment by a digital-to-analog converter located on the microcomputer 5 and the with it connected voltage divider 6, 7, 8, but via two separately on the microcomputer 5 connected digital-to-analog converters are determined. The advantage of this arrangement is then that the window width U1 - U2 of the switching thresholds can also be set is. The adjustment process takes place in such a way that, as in the first exemplary embodiment described, the open-circuit voltage UO is determined first after inserting a tape. For this purpose it is sufficient if the microcomputer 5 has one of the two digital-to-analog converters at the output of which a variable, rising or falling voltage is generated, that exactly then coincides with the open-circuit voltage UO, if that Output signal of the connected to the relevant digital-to-analog converter Comparator jumps from "High" to "Low" or from "Low" to "High". With the help of The microcomputer 5 determines the two symmetrically to the registered voltage value UO lying switching thresholds U1 and U2, which are then via the two digital-to-analog converters 11 and 15 are applied to the corresponding inputs of the comparators 3 and 4. The window width U1 - U2 is set so that possible fluctuations in the open-circuit voltage UO, the z. B. by not always uniform reflection properties of the upper and lower half of the strip can arise during the strip passage, within this window width remain.

This is an optimal automatic adjustment of the optoelectronic End-of-line shutdown guaranteed, with reliable detection of the start of the belt and End of tape is possible.

Fig. 3 shows a third embodiment of the invention. There is In contrast to the first two embodiments, only one optocoupler 1 ', 1 for Detection of the beginning of the tape and the end of the tape of the recording medium provided. So that the optocoupler can recognize both the beginning and the end of the strip, the switching foils on the tape used no longer have to be on the upper or lower half, but across the entire width or in the middle of the Record be attached to the support. The circuit is simplified compared to the arrangement in Fig. 2 so that in addition to the optocoupler 2 ', 2 also the comparator 4 and the digital-to-analog converter 15 are omitted. The cathode of the light emitting diode 1 G is connected directly to the negative pole of the voltage source 20. About a Resistor 21 is the emitter of phototransistor 1 and the inverting input of the comparator 3 is also applied to the negative pole of the voltage source 20. During the adjustment process, the microcomputer 5 first determines the open-circuit voltage UO, in that via the digital-to-analog converter 11 at its output a variable, rising or falling voltage is generated, which then precisely matches the rest voltage UO coincides when the output signal of the comparator 3 changes from "lot" to "high" or jumps from "High" to "Ko" with the help of the registered voltage value UO the microcomputer 5 determines the switching threshold U1 so that the comparator 3 is safe switches when the reflective foils enter the scanning area of the optocoupler. On the other hand, he selects the distance between the switching threshold U1 and the open-circuit voltage UO as follows large that the tape transport caused by fluctuations in the open-circuit voltage UO not undesirably interrupted by changing reflection properties of the strip material will.

This enables an optimal automatic adjustment of the optoelectronic End-of-line shutdown guaranteed. This adjustment is carried out after each insertion of a The tape is fed back into the recording device and also during the tape run constantly controlled by the microcomputer 5.

Claims (9)

- OPTOELECTRONIC 3-SAND END SWITCHING PATENT CLAIMS Optoelectronic Tape end switch for a video, audio or data recording and / or reproducing device with two optocouplers connected in series to detect areas of reflection at the end and beginning of the tape of the recording medium and with two to the optocoupler connected threshold switches, which are activated when defined input threshold values are reached change their output level, furthermore with a microcomputer that controls the threshold value switches incoming signals are processed and sent to the motor electronics that control the conveyor belt forwards that they are not to the optocoupler (1, 2) connected inputs (9, io) of the threshold value switch (3, 4) via a Resistor network (6, 7, 8) with the output (12) of a digital-to-analog converter (DAC) (11) are connected, its input (13) to a control output (14) of the microcomputer (5) is connected to the resistor network via the DAC sets the reference voltage (UR) so that the switching thresholds (U1) and (U2) symmetrical to the no-load voltage (UO) of the optocoupler. 2. Optoelectronic end-of-line shutdown according to claim 1, d a d u r c h g e k e n n n z e i c h -n e t that the threshold switches are used as comparators (3, 4) are formed, and that the not connected to the optocoupler (i) non-inverting input (9) of the first comparator (3) and not to the Optocoupler (2) connected inverting input (10) of the second comparator (4) are connected to the resistor network (6, 7, 8). 3. Optoelectronic end-of-line shutdown for a video, audio or video Data recording and / or reproducing device with two optocouplers connected in series for the detection of reflection areas at the end and beginning of the tape of the recording medium and with two threshold values connected to the optocoupler, which when reached of fixed input threshold values change their output level, furthermore with a Microcomputer that processes the signals coming from the threshold switches and forwards it to the motor electronics that control the conveyor belt, d a d u r c h e k e n n n z e i c h n e t that they are not connected to the optocoupler (1, 2) connected inputs (9, 10) of the threshold value switches (3, 4) with the outputs (12, 16) of two digital-to-analog converters (DAC) (11; 15) are connected, their inputs (13, 17) are connected to control outputs (14, 18) of the microcomputer (5), the via the DAC the switching thresholds (U1 U2) with a window width that can be specified as follows sets that the switching thresholds are symmetrical to the closed-circuit voltage (UO) of the optocoupler lie. 4. Optoelectronic end-of-line shutdown according to claim 3, d a d u r c h g e k e n n n z e i c h n e t that the threshold value switches are used as comparators (3, 4) are formed, and that the output (12) of the first digital-to-analog converter (11) connected directly to the non-inverting input (9) of the first comparator (3) and the output (16) of the second digital-to-analog converter (15) on the inverting one Input (10) of the second comparator (4) is located. 5. Optoelectronic tape limit switch for a video, audio or Data recording and / or reproducing device with an optocoupler for recognition of reflection areas at the end and beginning of the tape of the recording medium and with a threshold switch connected to the optocoupler, which switches on when of a specified input threshold value changes its output level, furthermore with a microcomputer that uses the Threshold switch coming Processes signals and forwards them to the motor electronics that control the conveyor belt, d u r c h e k e n n n z e i c h n e t that the is not connected to the optocoupler (1) Input (9) of the threshold switch (3) with the output (12) of a digital-to-analog converter (DAC) (11) is connected, the input (13) of which is connected to a control output (14) of the microcomputer (5) is switched, the difference between the switching threshold (U1) and the open-circuit voltage via the DAC (UO) so that only within the reflection areas at the beginning and end of the tape of the recording medium a reliable response of the tape limit switch takes place. 6. Optoelectronic end-of-line shutdown according to claim 5, d a d u notify that the threshold switch is used as a comparator (3) is formed, and that the output (12) of the digital-to-analog converter (1i) is direct is connected to the non-inverting input (9) of the comparator (3). 7. Optoelectronic conveyor limit switch-off after one or more of claims 1 to 6, d u r c h g e n n n z e i c h n e t that the microcomputer (5) the switching thresholds (U1, U2) only set when the reflection area at the end or beginning of the tape not in the optical send / receive area of the assigned Optocoupler (1, 2) is located. 8. Optoelectronic end-of-line shutdown according to claim 7 d a d u r c h g e k e n n z e i c h -n e t that the microcomputer (5) after already done End-of-belt shutdown starts the belt transport again until The reflection area at the end or beginning of the tape is no longer in the send / receive area of the assigned optocoupler (1, 2) is located. 9. Optoelectronic conveyor limit switch-off after one or more of claims 1 to 8, d u r c h g e n n n z e i c h n e t that the microcomputer (5) the switching thresholds (U1, U2) each time a tape is inserted into the recording and / or re-adjusts the playback device and constantly checks it while the tape is running. Description: