SU762015A1 - Apparatus for measuring pass factor of investigated object - Google Patents

Description

The invention relates to the field of automation and computer technology and can be used in systems for reading graphic and halftone information and in optical diagnostics systems. five

A device is known for measuring the transmittance of the object under investigation, which contains a series-connected light source, a photoelectric converter, an amplifier, and an analog-to-digital converter [1].

A disadvantage of the known device is the appearance of a measurement error due to the instability of the light flux of the light source and the sensitivity of the photoelectric converter.

It is also known a device for measuring the transmittance of a test object, which contains a light source optically coupled to a photoelectric transducer through a beam splitter, a mechanical breaker and a test object. The light source is also connected to the photoelectric converter only through a beam splitter and a mechanical interrupter 25. The output of the electrical transducer through the memory unit is connected to the division unit [2].

A disadvantage of the known device is its low speed, 30

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Caused by the fact that it uses a mechanical optical converter. The use of optical gates, operating on the principle of polarization of light and having sufficient speed, greatly impairs the resolution of the measuring system.

The closest in technical essence to the invention is a device for measuring the transmittance of a test object, comprising a first photoelectric converter, a first amplifier and a second photoelectric converter and a second amplifier, a dividing unit, an analog-digital converter, a light source and a luminous flux divider in series, moreover, the light source is optically connected through a light beam divider with photoelectric converters, input The dividing unit is connected to the outputs of the amplifiers, and its output is connected to an analog-to-digital converter [3].

The disadvantage of this device is the appearance of an error of the transmittance of the object under study due to the instability of the sensitivity of the first and second photoelectric converters.

762015

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The aim of the invention is to improve the accuracy of measurement of the transmittance of the object under study.

This goal is achieved by the fact that the first switch, the first integrator connected to the dividing unit, the second integrator whose input is connected to the first switch connected to the first photoelectric converter and its output connected to the dividing unit are connected in series are additionally introduced into the proposed device. the second switch, the third integrator and the comparison unit, the fourth integrator whose input is connected to the second switch connected to the second photoelectric at the converter, and its output is connected to a comparison unit, a second light source, optically connected to photoelectric converters and a control unit connected to light sources, switches, integrators and a comparison unit.

The drawing shows a functional diagram of the device for measuring the transmittance.

A device for measuring the transmittance of the object under study contains light sources 1 and 2, photoelectric converters 3 and 4, switches 5 and 6, integrators 7, 8, 9 and 10, dividing unit 11, comparison unit 12 and control unit 13.

The device works as follows.

According to the signal from the control unit 13, the switch 5 connects the integrator 7 to the converter 3, the switch 6 connects the integrator. 10 to the converter 4, and the light flux F1 appears at the output of the light source 1; part of the luminous flux (K1F1) passes through the object under study 14 with a transmittance τ and enters the input of the converter 3. The second part of the luminous flux (K2F1) is fed to the input of the converter 4. The electrical signals from the outputs of the converters 3 and 4 are accumulated in the integrators 7 and 10, respectively .

/ U, = / C ₇ D (3 ₃ τ _{Κ ι} Φ, ί / Ζ = Λ ', Ο ^ Φ, Ζ', (1)

about

where υ _Ί is the voltage at the output of the integrator 7;

KT - proportionality coefficient;

C ₃ - sensitivity of the transducer 3;

Ц ₁₀ = I ОЖ & ЗИ = К ₁₀ О, К _а Ф ₃ ί, (2) о

where C _about - the voltage at the output of the integrator 10;

Ko - coefficient of proportionality;

' four

C.-, - sensitivity of the transducer 4.

At time ίι, the signal from the control unit 13 turns off the light source 1, turns on the light source 2, switches 5 disconnects integrator 7 from converter 3 and connects integrator 8, switch 6 disconnects integrator 10 from converter 4 and connects integrator 9. Part of the light (Κ3Φ2 ) from the output of the light source 2 is fed to the input of the converter 3, and the second part of the luminous flux (Κ4Φ2) - to the input of the converter 4. The electrical signals from the outputs of the converters 3 and 4 are accumulated in the integrators 8, 9, respectively

and, = K ₃ (Ο ₃ Κ ₃ Φ ₂ άί = K * O ₃ K ₃ F & -K), (3) l

where _k - the output voltage of the integrator 8;

K & - proportionality coefficient;

and = =

ίι

= К ₃ О _1г К, Ф ₂ (ί - Λ), (4)

where% is the voltage at the output of the integrator 9;

Ko - coefficient of proportionality.

At time / g, when the voltage and _e at the output of the integrator 9 becomes equal to the voltage and ₁₀ at the output of the integrator 10, the comparison unit 12 is activated and, by its signal, the control unit 13 turns off the light source 2 and turns off the integrator 8 from the converter 3

_ Κ2Κ0ΦΙ1

^{2 1} ~ / eaten „F ₂

Substituting the value of / 2 — A into expression (3), we get

г г _ Κ2Κ ₃ Κ ₃ Κ] ο0 ₃ 4 ^> ιίί

* ~ KG "

The result of the division at the output of block 11 is equal to

After completion of the division operation, the control unit 13 clears all integrators.

The proposed device allows to significantly improve the accuracy of measurement of the transmittance of various transparent materials, media, photographs, etc.

Claims (1)

Claim Coefficient measuring device transmission of the object under investigation, containing the first light source, optically associated with photovoltaic converter 762015 five applicants, and a division unit, characterized in that, in order to improve measurement accuracy, it contains a first switch connected in series, a first integrator connected to division block 5, a second integrator, whose input is connected to a first switch connected to the first photoelectric converter, and its output is connected to a division unit, 10 second switch in series, a third integrator and a comparison unit, a fourth integrator whose input is connected to a second switch connected to the second otoelek6 its output is connected to a reference unit, a second light source optically connected to photoelectric converters, and a control unit connected to light sources, switches, integrators, and a reference unit.