DE1549784C - Photoelectric scanning device with threshold switches assigned to the photo elements - Google Patents

Description

The invention relates to a photoelectric scanning device with according to the markings a recording medium acted upon by a light source and photo elements assigned to them, switches generating output signals according to the scanned markings, their switching threshold in each case by one charged by the current of the photo element with full illumination Capacitor is determined.

In the photoelectric scanning devices for recording media, it is common to use the light-sensitive Sensing elements, such as photodiodes or phototransistors, to assign threshold switches that then generate an output signal when the current flowing through the photo element is a certain Value exceeds. These facilities are necessary because, for example, when scanning Punch cards, the light through the non-perforated areas of the recording medium not completely is absorbed, so that in these cases a certain photocurrent flows, which is also caused by printing the maps etc. can still be subject to considerable fluctuations.

A scanning device for punched cards is known from US Pat. No. 3,189,745, in which the threshold value for the delivery of an output signal due to the charging of a capacitor is determined. This capacitor is used before the start of scanning a card from the one under full lighting charged by the respective scanning photodiode current flowing. The time constant of the

is capacitor circuit is chosen so that the discharge time of the capacitor is large compared to the sampling time for a single card.

Since in this arrangement the switching voltages of the individual photodiodes of the charge of the assigned Capacitors and are not related to a fixed value, differences in the electrical properties of the individual photodiodes is eliminated. The disadvantage here is that the photodiode current to charge the capacitor via a transistor in an emitter follower circuit will. The resulting high input impedance slows down the switching speed and brings relatively large voltage jumps with it. There may also be changes in the gain factor adversely affect this transistor due to temperature fluctuations, aging, etc.

The object of the invention is to provide such a scanning device with regard to electrical stability to improve the threshold value switch, to increase the range of variation of the switching threshold value and a higher switching speed using smaller voltage fluctuations enable.

According to the invention this is achieved in that the switch by a differential amplifier with two In Darlington pair connected pairs of transistors is formed that in the first Darlington pair of transistors, the voltage at the through the maximum photocurrent through the first transistor charged capacitor determines the current through the second transistor, while the second, normally off pair of transistors then becomes conductive and over the second The transistor emits an output signal when the voltage generated by the photocurrent on the first transistor exceeds the instantaneous voltage of the capacitor. It is advantageous that the switchover threshold determining capacitor directly to the emitter of the first transistor of the first Darlington pair connected is.

The circuit designed in this way prevents voltage fluctuations, including those caused by Temperature effects and signs of aging arise, balanced. The charging of the capacitor takes place via a low input impedance. The resulting increase in switching speed results in a lengthening of the duration of the output pulses, thereby increasing the duration of the output pulse Security in the identification of the signals is achieved.

The capacitor is advantageously charged via a voltage divider in such a way that the changeover corresponding to its maximum charge

voltage is a certain fraction of the maximum input voltage generated by the photo element.

By increasing the switching speed, the recharging of the possibly up to just above the lower limit value during the scanning of a recording medium the marker recognition discharged capacitor through the full illumination of the photo element take place in the space between two recording media passing through the device.

The invention is described using an exemplary embodiment illustrated by the drawings. Show it:

1 shows a schematic representation of a scanning device for punch cards with the threshold switch according to the invention,

F i g. 2 shows a diagram to explain the dependence of the duration of the output pulses on the Switching speed and

F i g. 3 shows a diagram to explain the dependence of the level of the switching voltage on the Maximum input peak voltage level.

In the scanning device shown in FIG. 1, the punch cards 10 with the perforations 11 from the card magazine 12 through the card knife 13 and the transport rollers 14 successively. Further transport rollers 14 transport the cards to the scanning device and from there to the card tray 20. The scanning device consists of the light source 17, the light of which is incident in a row across the card path arranged phototransistors 18 falls. The arrangement of the phototransistors 18 corresponds to Index positions of the cards to be scanned. The emitters of the phototransistors 18 are each with a Amplifier circuit connected. Since these circuits are identical to one another, only one is used below of which described.

Each phototransistor 18 has its collector at + 6 volts and its emitter is connected to the voltage divider formed from the resistors R 1 and R 2 via the resistor R 3 to the base of the transistor T 3. The resistors R 1 and R 2 have a relatively low impedance. Their values are in FIG. 1 specified. The voltage divider is across the resistor / ?! in bulk. The connection of the resistors R 1 and R 2 leads to the base of the transistor Tl. The emitter of this transistor is connected to the base of the transistor T 2 and is also connected to ground via the capacitor Cl. The collectors of the Darlington-connected transistors T1 and Γ 2 are at the potential + 6 volts. The emitter of the transistor T 2 is connected to a voltage of -3 volts via the resistor R 4. The emitter of the transistor T 3 is connected to the base of the transistor T 4, and the collectors of these two transistors connected in a Darlington circuit are connected to +24 volts via the resistor RS.

The emitter of the transistor T 4 is connected to the emitter of the transistor T 2. In this way, a differential amplifier is formed, the output of which is taken from the collector of the transistor T 4. In the present case, this output is connected to the base of the transistor T 5 , the collector of which is at +6 volts and the emitter of which is connected to the potential of -3 volts via the voltage divider formed by the resistors R 6 and R 7. The branch point of this voltage divider leads to the base of the transistor T 6, the collector of which is connected to +3 volts via the resistor R 8. The emitter of this transistor is connected to ground.
The operation of the Tranisstors Tl is conducive to applying a charge to the capacitor Cl zn. Voltage jumps, ie the base-emitter voltage drops of the Darlington-connected transistors T1 and Γ 2

ίο are compensated for by voltage jumps in the transistors TZ and T 4, which are also connected in a Darlington circuit. The switching threshold value determined by the capacitor C1 is a certain fraction of the maximum input potential generated by the phototransistor 18 and is therefore a function of the current flow through the phototransistor 18.

The current carried by the phototransistor 18 reaches its maximum value when, e.g. B. in the absent-being a card or when scanning a hole in the card, the phototransistor is full Light from the light source 17 receives. This maximum current can be due to changes in gain of the transistor or changes to the light source are subject to certain fluctuations.

In the absence of a perforation, the light is transmitted through the recording medium either completely blocked, or a certain percentage will pass through the card. In the present For example, the amplifier does not switch and therefore does not provide an output signal if the translucent The amount of light does not exceed approximately 18% of full light.

The phototransistors receive full light after a card has left the scanning station and the next card to be read has not yet been fed. Since the full light in the phototransistors 18 generates a maximum current flow that is dependent on the respective light intensity, a threshold value for the switchover is established before each card is displayed. Under these conditions, a voltage reaches the base of the transistor T 1 via the resistor R 1, which makes it conductive. The capacitor C 1 is charged until the highest input potential is reached. This is the case shortly before the point in time at which the leading edge of the next fed card covers the light from the phototransistor 18. This reduces the current to such an extent that the polarity of the transistor T1 is reversed and goes into the blocking state. The switching threshold value is maintained by the capacitor C 1 for the duration of the scanning of a card.

During the time in which the phototransistor 18 receives full light, the transistor Γ 2 is in the conductive state, but not in saturation. Its emitter potential is proportional to the charge on capacitor C1. The transistors T 3 and T 4 are in saturation. The transistor T 5 is conductive to a small extent, and the transistor T 6 is switched off under the conditions described, since its base is negative with respect to its emitter. The transistor TS is never completely switched off. He still conducts something when the transistor Γ 4 is in saturation and is fully conductive when the transistor T 4 is blocked.

When a card covers the light from the phototransistor 18, the transistors Tl, Γ3 and Γ4 are im

Lock state. The transistor T 2 is fully conductive due to the charge on the capacitor C 1. The capacitor C1 is then slightly discharged. When the transistor T 4 is switched off, the base of the transistor T 5 is more positive, and therefore this transistor conducts more than when T 4 is conductive. When the transistor T 5 is fully conductive, the base of the transistor T 6 becomes more positive than its emitter, T 6 therefore becomes conductive. The transistor T 6 is blocked when the light acting on the phototransistor 18 is sufficient to generate a voltage which exceeds the switching level on the capacitor C 1. When this is the case, ie when a perforation is sensed, the transistors T 3 and T 4 become conductive. The transistor T 5 is less conductive and the transistor Γ 6 switches off. If then the luminous flux hitting the phototransistor 18 decreases when a perforation leaves the area of the phototransistor, the input voltage drops below the switching threshold value, so that the transistors T 3 and T 4 switch off. This makes the transistor TS more conductive and the transistor T 6 switches on. The duration of the output pulse at transistor T 6 corresponds to the time during which this transistor is switched off.

F i g. Figure 2 shows that the output pulse has a longer duration when the phototransistor 18 is not is due to a high input impedance. The dashed and solid lines represent Output pulses when the current of the phototransistor is supplied to a low and a high impedance will.

In the present case, the impedance is approximately 2.8 KOhm. With a minimum current of 300 microamps. the minimum peak voltage is approximately 840 millivolts. With a maximum input current of 2.1 milliamps. the maximum input peak voltage is 5.88 volts. Since the switching voltage is set between two cards, it varies as a function of the input peak voltage. This is shown in FIG. 3. The switching level corresponding to pulse A is higher than that corresponding to pulse B because the peak of pulse A is greater than the peak of pulse B.

1 sheet of drawings

Claims (4)

Patent claims: 1. Photoelectric scanning device with photo elements acted upon by a light source according to the markings of a recording medium and associated with them, corresponding to the scanned markings generating output signals, the switching threshold value of which is determined by a capacitor charged by the current of the photo element with full illumination, characterized in that the Switch is formed by a differential amplifier with two pairs of transistors (Tl, T2 and T 3, T 4) connected in Darlington circuit, that in the first Darlington pair of transistors (Tl, T2) the voltage on the through the maximum photocurrent over the first transistor (T 1) charged capacitor (C 1) determines the current through the second transistor (T 2), while the second, normally in the blocking state, pair of transistors (T 3, T 4) then becomes conductive and via the second Transistor (T 4) emits an output signal when the photocurrent at the first transistor (T 3) generated voltage exceeds the instantaneous voltage of the capacitor (Cl). 2. Scanning device according to claim 1, characterized in that the switching threshold value determining capacitor (C 1) directly to the emitter of the first transistor (Tl) of the first Darlington pair. 3. Scanning device according to Claims 1 and 2, characterized in that the capacitor (C 1) is charged via a voltage divider (R 1, R 2) in such a way that the switching voltage corresponding to its maximum charge is a certain fraction of that generated by the photo element maximum input voltage. 4. Scanning device according to claims 1 to 3, characterized in that the recharging of the capacitor (C 1) in each case by the full illumination of the photo element (18) in the There is an intermediate space between two recording media (11) passing through the device.