SU423088A1 - DENSITOMETER - Google Patents

Description

one

The invention relates to a motion picture photo., In particular, to the field of control of the sensitometric properties of photographic materials during their production.

Densitometers are known that contain an illuminator with an optical system in the form of two branches: a measuring and a reference with a photoelectric multiplier (PMT), a mechanical light modulator, an analyzer made in the form of two channels with a light-optical system and photodetectors in each, a measuring wedge with the following recording drive characteristic curve and sensitogram with a drive. However, these densitometers do not automatically provide a characteristic curve on the form.

The proposed densitometer includes hardwired code lines with several dashed paths, each connected to a measuring wedge and sensitogram, each connected via photo cells to reversible counters and logic cells, at the output of which printers are installed.

The drawing shows the functional diagram of the densitometer.

A densitometer, made in a two-beam measuring circuit, consists of illuminator 1, from which light is directed along two branches: measuring A and supporting B, and a capacitor

2 and diaphragms 3, mirrors 4 and diaphragms 5, of the mechanical modulator 6. In the measuring branch, after the modulator, are the lens 7, the measuring wedge 8, rigidly

associated with the application of the characteristic curve, for example, the recorder 9, on the sensitometric form 10 and the analyzer code line 11, the table with the measured sensitogram 12, rigidly associated with the code line 13 and the photomultiplier 14. In the reference branch B are located after the modulator 6 compensation wedge 15, translucent mirror 16 dividing the light beam into two, one of which falls on the photodetector of the auxiliary signal 17, and the second through the flexible light guide 18 on the photomultiplier 14, the follower drive 19 of the characteristic curve recording, the drive 20 sensitograms mmy

Code line 11 has two tracks of holes 21 and 22. The track of holes 21 is proportional to the distribution of densities of the measuring wedge 8 with a spike of 0.1 units of density and is used when measuring contrast ratios. The path of the holes 22 is also proportional to the density distribution of the wedge 8, but with a pin of 0.01 density units, and is used to measure densities. The information from line 11 is read using a single analyzer channel in the form of an optical-optical system of an incandescent bulb 23, a lighting diaphragm 24, and photodetectors 25 and 26.

Code line 13 has five wide openings 27–31. The path of the holes 27 of the progression of the photosensitivity scale on a sensitometric blank is used when measuring the photosensitivity. The track of holes 28 is proportional to the order of the sensitivity scale of the sensitometric blank and is used for the printing device of the photosensitivity values. A path of holes 29 determines the magnitude of the exposure scale sections when quantizing a characteristic curve to determine its gradients. Track 30 has only one hole for issuing a DQ command to a non-loose device. Track 31 also has only one hole for issuing a command to the nexatus as well.

The information from line 13 is also read from the other channel of the analyzer in the form of a light opaque system 32, a lighting diaphragm 33, and photon receivers 34-38. Signals in the form of rectangular pulses from photocensors 25, 26, 34, 35, 36, 37, and 38 are sent to reversible counters 39-41, external devices 42-44, to switch 45, and to logic cells 46-48.

Densitometer works in the following way.

In the absence of a sensitogram, the light beams of both branches A and B, modulated in antiphase by the mechanical 1 modulator 6, fall on the photocathode of the PMT 14. The tracking system compensation is achieved by moving the measuring wedge 8 using the following drive 19. The wedge 15 is manually shifted to zero system position. At the moment of the compensation equilibrium of the servo system, the light signals on the photocathode of the PMT are equal, and the input of the actuator 19 is only an auxiliary signal from the photo receiver of the secondary signal 17.

With the introduction of the measured sensitogram 12 into the measuring branch A at the output of the photomultiplier 14, an error signal appears, and the follower actuator 19 moves the wedge 8 before the onset of compensation. Since the sensitogram together with the code line 13 moves uniformly by the drive 20, both the measuring wedge with the code line 11 and the recorder 9 are moved by the drive 19, maintaining the compensation state. The pattern of motion of the measuring wedge corresponds to the density distribution on the densitogram. The recorder 9 draws a characteristic curve on the sensitometric form 10. When moving lines II and 13 in the light beams formed by the lamps 23 and 32 and the lighting diaphragms 24 and 33, the light signals from the dashed paths are removed by the photodetectors 25, 26, 34, 35, 36, 37 and 38, and are formed into nr-angle electric pulses.

The electrical pulses formed by the track 22 of the ruler 11, proportional to the distribution of densities but the length of the measuring wedge, from the photo-prime 26 arrive at

is intact:; its device 42 (Do and Oman) and the logical cell “And 48.“ print the typed value of Z).) numerically goes to the signal point from track 31 of the code line 13 through the photodetector 34.

The “print typed Z” s, ai, -c signal arrives at the moment when the signal from the track 30 of the ruler 13 is fed through the photodetector 35.

The electrical impulses formed by the road yu 21 line 11 and the photodetector 25,

served on the reversible counters 40 and 41 and on the logical row "AND 47. Counters 40 and 41 are switched alternately for addition and subtraction by the switch 45. Switching signals come from the dashed line 29

ruler 13 through a photodetector 36. The dashed line 29 of ruler 13 determines the magnitudes of the segments of the exposure scale DlgI when quantizing the characteristic curve to determine the gradients of the characteristic

crooked.

The sequence of impuls from the photo source 25, the number of which is determined by the density of the densitogram as it moves by the value of Alg

the counters 40, 41 and the cell “And 47. When the first period of the track 29 of the code line 13 passes, the sequence of pulses from the photodetector 25 enters through the logical cell“ And 47 to the printing

the device is summed by the reversible counter 40. In this case, the input to the counter 41 is closed and at the same time there is a signal from the output of this counter. This signal by means of the “OR 46” cell provides

sequence of impulses through a logical cell “And 47 on the printing device during the passage of the first period of the bar track 29 of the code rule 13.

The next impulse from the photodetector 36, corresponding to the second period of the track 29 Liiyaki 13, through the switch 45 will put the counter 41 into the summation mode, and the counter 40 into the subtraction mode. Pulse sequence corresponding to the second section

AlgH is summed by counter 41 and subtracts the previously accumulated sequence of pulses from the reversible counter 40. At this moment, the logical cell "OR 46 cell" And 47 is closed for the passage of pulses

on the printing device 44.

In view of the fact that the gradient of the characteristic curve initially increases, it is obvious that the number of irregular pulses from site to site will increase. Consequently, the sequence of pulses corresponding to the second section of AlgI will be larger compared to the number of pulses of the first section. The excess number of pulses of the second section enters the device 44,

since, when the previously recorded pulses are completely subtracted, a signal is received at the output 40 at its output, which, after 46, opens a logical cell 47. In subsequent sections D1G, this process is repeated and thus the printing device is set to the maximum gradient position. The value of the maximum gradient is printed by the signal from track 30 of the ruler 13.

Photosensitivity is determined using the nggr. Tracks 27 and 28 or tracks 13. Track 27 is proportional to the opener sensitivity of the photosensitivity on a sensitometric form. Track 28, the proportional discharge of the same sensitivity scale, through the photoreceiver 37, gives signals for transferring the bits of the printing device 43. A sequence of pulses, prolortional to discrete values of photosensitivity, from track 27 of the code 13 unit through the photodetector 38 goes to the device 43. By a signal to print DO the logical cell "I 48" is opened from the photo-receiver 34 through the switch 49, and the current values of densities in the form of electrical pulses from the photo-receiver 26 are fed to the counter 39. After the number These pulses will reach 20 and 85, corresponding to a density level of 0.2 and 0.85, i.e., the sensitivity criteria, from the output of the counter 39, the signal "print the sensitivity values" is displayed.

Prev Invention

A densitometer containing a illuminator with an optical system in the form of two branches: an measuring tube and a supporting one with a photomultiplier tube, a mechanical light modulator, an analyzer made in the form of two channels with a light-optical system and photodetectors in each, a measuring wedge with a following drive. This is a recording of the characteristic curve of the second cycle with a drive, characterized in that, in order to automate the obtaining of the characteristic curve

on the form, code lines with several dashed paths, each connected through a photoelectric sheet with reverse counts and a log1; cheshg1lP1 cells, at the output of which print printable patterns are entered, are rigidly connected to it, respectively, with the measuring wedge and to the sonicator.