SU885058A1 - Analytic device for automatic electronic engraving machines - Google Patents

Description

(54) ANALYZING DEVICE FOR ELECTRO-CAMERA AUTOMATIC SYSTEMS

I

This invention relates to analyzing devices for engraving machines.

An analyzing device for electrogravating automats is known, which contains a light source, through an optical system connected to a photosensor, and a gain unit (I.

The disadvantage of the known device is; The low analysis efficiency is low.

The purpose of the invention is to improve the quality and effectiveness of the analysis of the original when reading it.

 The goal is achieved by the fact that a1Antizing device for electrogravating automats, containing a light source, connected through an optical system to a photosensor, and a amplifying unit, has a switch and an impedance unit; the switches are connected to the second input of the resistance unit and the first input of the gain unit, the second input of which is connected to the output of the resistance unit.

In addition, the resistance unit has a constant resistor and variable resistors, the sliding contacts of which through a switch and a constant resistor are connected to one of the inputs of the gain unit.

In this case, the photo sensor is made in the form of a photodiode. FIG. 1 is a schematic diagram of the analyzer; in fig. 2 - dependence of the output signal of the analyzer with a smooth reading of the original., Linearly varying IQ in density from large in the direction of smaller density values in the Negative - mode, in FIG. 3 - dependence of the output resultant signal of the analyzer on the density of the original with a linear variation of plutality from the greatest, towards the least 1 $ in the “Positive” mode, while a is the change and only from the photo-EMF signal from the photosensor, b is a constant the negative voltage Uebw obtained from the slider of the resistor R 10; Direct S is the resultant output voltage obtained as a result of calculating the simulated and changing ALARM.

Claims (3)

The device (Fig. I) contains a stabilized power source I, a light source 2, optical systems 3 and 4, an original shaft 5, a diaphragm 6, a photo sensor 7, a switch Negative Positive, a variable resistor 9 of zero output voltage in mode " Negative, variable resistor 10 of zero output voltage in positive mode, additional terminating resistors 11-14, integrated operational amplifier 15, potentiometer 16 balancing the operational amplifier, negative feedback divider on resistors 17 and 18, and load resistance ican 19, the diode 20. The optical systems 3 and 4 have focusing systems. Aperture 6 is located at a focal distance from the optical system. The resistance unit has variable resistors 9 and 10 and an additional terminating resistor 11. The gain unit includes additional terminating resistors 12-14, an integrated operational amplifier 15, a potentiometer 16, a divider 17 and 18 negative feedback, a load resistor 19 and a diode 20 After switching on, the analyzing device operates as follows. The stabilized power supply source I ensures the constancy of the light flux from the source 2 of the light through the focusing optical system 3 and in the form of a bright bright point on the original located on the shaft 5 of the original. The light flux reflected from the original, proportional to the density of the read point, through the optical system 4 and the diaphragm 6 hits the photosensitive photosensor 7. The light flux in the photosensor (photodiode) 7 is converted to a photo-EMF, which through the switch 8, allowing the photodiode connection to change, and an additional terminating resistor 12 is supplied to the non-inverting input of the integrated operational amplifier 15. Resistor 12 serves to eliminate the effect on the output signal parameters of variations in the magnitude of the internal resistance effects of photodiode 7 arising from a change in ambient temperature. In order to obtain repeatability (stability) in magnitude of the output signals of the analyzer from different densities of the tone pattern of the original and taking into account the importance of issuing undistorted information, the operational amplifier (OU) 15 is covered by external negative feedback made on resistors 17 and 18, and the OU itself is powered from a stabilized power source 1. The negative feedback signal is applied to the inverter input of the op-amp via an additional matching resistor 13. Resistor 16 is designed to balance the op-amp in the absence of input signals. Resistors 11--14 serve to match the circuit elements. Resistor 19 is a load. Diode 20 eliminates the POSSIBILITY of outputting the output signal to external circuits of reverse polarity if the sliding contacts of variable resistors 9 and 10 are inaccurately installed. In the Negative mode, the analyzer works as follows. Switch 8 is set to Negative. The negative polarity of the photo-emf from the photodiode 7. Through the switch 8 and the additional resistor 12 is fed to the non-inverting input of the op-amp, therefore a negative polarity signal is output from its output, varying linearly in magnitude depending on the density of the original readable (Fig. 2) ). At the same time, the lighter fields correspond to a larger value of the output signal from the analyzer. Since the sensitivity of modern operational amplifiers is high and sometimes engraving in the region of high original densities requires signal limiting, the analyzer circuit has a variable resistor 9, the sliding contact of which in the Negative mode is connected to the inverter input of an op-amp. The variable resistor 9 is energized by a negative stabilized voltage, and if a voltage is output from its sliding contact, then it is of positive polarity at the output, i.e., inverse to the primary. signal. This can compensate for the desired initial signal value. In the mode “Positive device works as follows. Switch 8 is set to Positive. In this case, a non-inverting input of the op-amp is fed with a photo-emf of positive polarity. At the same time, at its output the signal is also positive polarity. At the same time, a positive polarity signal is received from the variable resistor 10 through the switch 8 and the resistors 11 and 13 together with the negative feedback signal to the inverting input of the op amp. This positive polarity signal is of such magnitude that it, amplified and inverted, generates a negative polarity signal at the output of operational amplifier 15 equal to the amplified positive polarity signal received from the photodiode 7 at the moment of reading the original of the white polar field. .t e. the lowest density and, therefore, the maximum in magnitude. As a result of summation of 2 signals, equal in magnitude and opposite in polarity, the total signal at the output of the OA 15 is zero. When reading the original and smoothly changing its density from lower densities to a larger resultant signal at the output of the op-amp 15, it is also smoothly and with the same pattern of growth, since the signal from the sliding contact of the variable resistor 10 does not change, and the subtracted signal from the photodiode 7 is intelligent, when reading large densities (most dark fields) of the original. The analyzer allows, if necessary, to limit the signal in the field of bright fields. To do this, it is enough not to decompensate the main signal by the variable resistor 10 by the required amount. Then, when reading the lightest fields of the original, the total signal at the output of the op-amp 15 has a positive value, but not well MMCtrl ni JlU / nn 1: Lop jr ntttimnnj, ate “iv - nj left a diode 20 does not give a positive polarity signal to external circuits. The use of the proposed analyzer improves the quality and efficiency of the analysis of the operation of electro-engraving machines due to the fact that the dynamic range of the device is dramatically higher, since the entire input range of the OS is used only for the main signals representing the density of the original; In the photo-emf mode, the photodiode has no tempo currents. In addition, it is possible to limit both the smallest and the largest signal regions, and thereby stabilize these areas; in the device, the input of the op-amp does not fall into the power source ripple, which eliminates the appearance of additional interference in the main signal circuits; the device allows, when reading the same original, to give information about it both in a negative and in a positive display. Claims. An analyzing device for electrogravating automata containing a light source, through an optical system connected to a photosensor, and a reinforcement unit, characterized in that, in order to improve the quality and effectiveness of the analysis of the original when it is read, it has a f - i, a switch and a resistance unit one of the switch clamps is connected to the contacts of the photo sensor and the first inputs of the resistance unit, the other clamps of the switch are connected to the second input of the resistance unit and the first input of the gain unit, the second input to torogo connected to the output unit resistances. 2. A device according to Claims I, characterized in that the resistance unit has a fixed resistor and variable resistors, the sliding contacts of which through the Switch and the fixed resistor are connected to one of the inputs of the gain unit. 3. The device according to claim 1, characterized in that the photosensor is made in the form of a photodiode. Sources of information taken into account during the examination 1. Patent of Germany No. 2361903, cl. B 41 C 1/04, / Wxplotn / wrx AMeuffcat min dense Kyu