CS257652B1 - Wiring for setting the output voltage of the linear image sensor - Google Patents

Abstract

The subject of the solution is a circuit for adjusting the output voltage of a linear image sensor. The output voltage of the linear image sensor is supplied in parallel via the first and second switches, the second and first input resistors to the inverting and non-inverting inputs of the first operational amplifier. The first and second switches are controlled by the first and second driver circuits. The first driver circuit is controlled by the voltage corresponding to the first shift register, the second driver circuit by the voltage corresponding to the second shift register of the linear image sensor. In the first operational amplifier, the voltage difference of both shift registers, even and odd, is evaluated, and the compensation voltage is supplied to the inverting input of the second operational amplifier, to whose non-inverting input an auxiliary DC balancing voltage from a potentiometer is supplied. The second operational amplifier subtracts these voltages and the balancing voltage, which ensures identical voltages from both shift registers, is supplied to the balancing input of the linear image sensor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit for adjusting the output voltage symmetry of a linear image sensor comprising an integrated circuit consisting in part of a plurality of photosensitive elements onto which the measured object is projected and electronic signal processing auxiliary circuits consisting of separating circuits, shift registers. output amplifier ·

Linear image sensors are used for measurement of dimensions in industrial applications · Measured object is projected by optical system on the surface of photosensitive elements, whose number varies according to the type of sensor in the range of 110 - 3 800 and their distance is about 10 - 20 version ·

In the area of these elements, an electric charge is generated in the area of illumination, the magnitude of which is proportional to the size of the illumination. · In places that are not illuminated, the electric charge is not produced. two parallel shift registers. The internal arrangement of the linear image sensor is such that the electrical charges from the odd photoelectric elements are transferred to one shift register, the charges from the even photoelectric elements to the other register. The conversion of the electrical charge from the linear photosensitive elements of the linear image sensor is effected via the separation circuits. The electrical charges that are now in the shift registers are successively applied to the output amplifier of the linear image sensor * at the output of which is an image voltage proportional to the illumination size of the respective photosensitive element of the sensor. The internal arrangement of the linear image is realized by alternately feeding electrical charges from one and then the other shift register to the output amplifier.

The above process of image signal processing is periodic. This means that the measured object is displayed on the surface of the photosensitive elements during the scanning period, after which the accumulated electric charge is transferred to parallel shift registers and their gradual emptying is ensured by shifting pulses. During the emptying of the registers, the measured object is projected again on the surface of the photosensitive elements. · After the emptying of the displacement registers is finished, the rewriting follows, ie the charge is transferred to parallel displaceable registers and the above described charging process is repeated.

As a result of the unequal design of the shift registers, an asymmetry appears at the output of the linear image sensor. This means that the output voltage obtained from the odd photosensitive elements is different from the voltage from the even photosensitive elements. that is, with the amount of illumination. The linear image sensor has a separate symmetric input where the voltage can be adjusted to adjust the output voltage symmetry of the linear image sensor. The disadvantage of this solution is that this symmetry is set for only one illumination, it breaks when the illumination changes and would need to be reset. This limits the illumination dynamics of the element. The output voltage symmetry is also temperature dependent. When used in industry for a wide range of operating temperatures, as a result of asymmetry or temperature dependence, errors in the measured dimension data occur.

This non-phosphorically eliminates the circuit for adjusting the output voltage symmetry of the linear image sensor according to the invention, wherein the pulse generator output is connected to the input of the control logic circuit, which is connected to the first to sixth input of the linear image sensor . The voltage output of the linear image sensor is connected both to the collector of the first switch whose emitter is connected through the first input resistor to the non-inverting input of the first opamp and second to the collector of the second switch whose emitter is connected through the second input resistor to

- 3 inverting input of the first opamp. On the basis of the first switch, the first output of the control logic circuit is connected via the first excitation circuit, and on the basis of the second switch, the third output of the control logic circuit is connected via the second excitation circuit. A first capacitor and a first limiting diode are connected in parallel between the emitter of the first switch and the neutral terminal, and a second capacitor and a second limiting diode are connected in parallel between the emitter of the switch and the neutral terminal. via a third input resistor connected to the first terminal of the third capacitor and to the inverting input of the second operational amplifier. Its non-inverting input is connected via a potentiometer to the neutral terminal, to which the second terminal of the third capacitor, which together with the third input resistor forms a filter element, is also connected. The output of the second opamp between which a second feedback resistor is connected and its inverting input is connected to the symmetric input of the linear image sensor.

A particular embodiment of the invention is shown in the attached drawing.

The output of the pulse generator 1 is connected to the input of the control logic circuit 2, which is connected to the first to sixth inputs 31 to 36 of the linear image sensor by its first to sixth inputs 21 to $. Its voltage output 8 is connected both to the collector of the first switch 6 whose emitter is connected via the first input resistor 17 to the non-inverting input of the first operational amplifier 10 and second to the collector of the second switch 6 whose emitter is connected via the second input resistor 16 to the inverting. input of the first operational amplifier 10. On the basis of the first switch 6, the first output 21 of the control logic circuit 2 is connected via the first driver circuit 8, and on the basis of the second switch X the third output 23 of the control logic circuit 2 is connected via the second driver circuit 2. Between the emitter of the first switch 6 and the neutral terminal, the first capacitor 12 is connected in parallel and the first limiting diode 14 * between the emitter of the second switch 2 and the neutral terminal is parallel connected the second capacitor 13 and the second limiting diode 15. and its output, which is

4 via a third input resistor 18 connected to the first terminal of the third capacitor 20 and to the inverting input of the second operational amplifier. Its non-inverting input is connected via a potentiometer 21 to a neutral terminal, to which is simultaneously connected the second terminal of the third capacitor 20, which together with the third input resistor 19 forms a filter element. resistor 22, is connected to the symmetry input 5 of the linear image sensor 3 ·

The advantage of the solution according to the invention is the automatic adjustment of the output voltage symmetry on the one hand according to the size of the video signal, ie according to the change of the light intensity and on the other hand according to the instantaneous working temperature. The symmetrical voltage appears at the output of the linear image sensor even in the case of unequal design of shift registers, sensing electric charges from even and odd photosensitive elements of the sensor. When measuring physical dimensions in industrial applications, for example the transverse dimension of cable products, accurate values are obtained, independent of changing external conditions.

The operation of the linear image sensor 3 with the individual photosensitive elements 41, 42 - 4n is controlled from the pulse generator 1 by the control logic circuit 2. In this control logic circuit 2, all pulses are generated to control the linear image sensor 6. On the first output 21 of the control logic circuit 2 the shifting pulse voltage of the first shift register of the linear image sensor 3 appears, on the second output 22 of the control logic 2 the shifting pulse voltage of the first shift register in the inverse shape. the fourth output 24 to the shifting pulse voltage of the second shift register in inverse form. A transient pulse voltage for the first shift register of the linear image sensor 2 appears at the fifth output 25 of the control logic circuit 2, and a transient pulse voltage for the second shift register at the sixth output 26. The output voltage of the linear image sensor 2 is applied from the voltage output 6 in parallel via the first and second switches 6 and 2 ^{to the} non-inverting and inverting input of the first operational amplifier 10. The first and second switches 6 and 7 are realized by transistors _; in a specific embodiment of the appended drawing, LOS transistors that are most suitable for such applications are used.

The first switch 6 is controlled by the first excitation circuit 8 and the second switch 2 by the second excitation circuit 2. The shifting pulse voltage of the first shift register of the linear image sensor 2 is applied to the input of the first excitation circuit 8. This means that the first excitation circuit 8 is controlled by a voltage corresponding to the first shift register and the second excitation circuit 2 by a voltage corresponding to the second shift register. A first capacitor 12 is connected between the output of the first switch 6 and a neutral terminal, and a second capacitor 13 is connected between the output of the second sensor and a neutral terminal. A DC voltage component is formed on the first and second capacitors 12 and 13. capacitor 12 for odd and on the second capacitor 13 for even photosensitive elements.

In parallel to the first capacitor 12, a first limiting diode 14 is connected and to the second capacitor 13 a second limiting diode 15. The first and second limiting diodes 14 and 15 limit the negative overshoot caused by the operation of the linear image sensor 2 at its output.

In the first operational amplifier 10, the voltage difference of the two shift registers of the linear image sensor 3 is evaluated and at the output of the first operational amplifier 10 is a compensating voltage * which is applied to the inverting input of the second operational amplifier 11 via a filter element. The value of this filter element is selected so as to obtain optimal adjustment at the symmetric input 2 of the linear image sensor 2. The non-inverting input of the second operational amplifier 11 is supplied with DC auxiliary symmetric voltage from the output of the potentiometer 21. the opamp 11 'determines the amplification size. The second operational amplifier 11 subtracts the DC voltage at the inverting input voltage supplied from the output of the first operational amplifier 10. symmetrizing input linear image sensor 2 2 3 ^{2 θ} output of the operational amplifier 11 symmetrizing applied voltage that ensures equal stress on both shift registers.

Claims (1)

P 5 E D M Y T OF THE INVENTION Circuit for setting the symmetry of the output voltage of a linear image sensor consisting of an integrated circuit, consisting in part of a series of photosensitive elements, on which the object to be measured is projected, and auxiliary circuits for electronic signal processing. in that the output of the pulse generator (1) is connected to the input of the control logic circuit (2), which is connected with its first to sixth outputs (21 to 26) to the first to sixth inputs (31 to 36) of the linear image sensor (3); the voltage output (4) is connected both to the collector of the first switch (6), the emitter of which is connected via the first input resistor (17) to the non-inverting input of the first operational amplifier (10) and via second input resistor (I6 $ inverting input first The first output (21) of the control logic circuit (2) is connected via the first driver circuit (8) and on the basis of the second switch (7) via the second driver circuit (9) connected to the third output (23) of the control logic circuit (2), the first capacitor (12) and the first limiting diode (14) are connected in parallel between the emitter of the first switch (6) and the neutral terminal and the second capacitor (13) and the second limiting diode (15) are connected in parallel, the first feedback resistor (18) being connected between the inverting νείμρ of the first operational amplifier (10) and its output which is connected via a third input resistor (19) firstly to the first terminal of the third capacitor (20) and secondly to the inverting input of the second operational amplifier (11), whose non-inverting input is connected via a potentiometer (21) to the neutral terminal, to which it is connected a coil terminal of the third capacitor (20) is connected at the same time, e.g. the output of the second operational amplifier (11), between which and its inverting input a second feedback resistor (22) is connected, is connected to the symmetrization input (5) of the linear image sensor (3) o