DE2434905A1 - BEAM RECORDER - Google Patents

Description

Siemens Aktiengesellschaft Erlangen, July 2, 1974

Henkestrasse 127

VPA 74/5905 Lst / Sin

Stra hlschreiber

A jet pen according to the preamble of the patent claim allows lines to be recorded on a recording medium » A large number of lines are recorded parallel to one another on the recording medium and in their intensity modulated so it is possible to record an image » In known liquid jet recorders, the intensity of the recorded lines is modulated by modulation of the liquid jet and with known light detectors It is possible to change the luminous flux from the recorder to the recording medium.

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A jet recorder in which a liquid jet "is used for image recording is" described, for example, in DT-AS: 1 271 754. In this known liquid jet recorder, the liquid jet is modulated by a deflection electrode between the nozzle ejecting the liquid jet and the recording medium. A high voltage is applied to this deflection electrode for spray atomization. The construction of such a liquid jet writer is very complicated and expensive, in particular because the liquid ejected by the nozzle and not used for writing must be collected and fed into an ink reservoir and because a special control electrode must be present in connection with a control circuit for jet modulation got to:. The known light beam writers have the disadvantage that the intensity of the light beam only relatively: You can change slowly so that no high write speeds & τ- are targetable.

The invention is based on the object, a beam recorder according to to create the preamble of claim 1, dler it: allows an image to be written line by line on a recording medium with simple means.

According to the invention, this object is achieved by the features of the characterizing part of claim 1. The invention lies based on the idea that an intensity modulation of a recorded Line with a constant recording beam is possible in that the recording beam with a speed is performed on the recording medium, whichever corresponds to the desired intensity. The jet pen according to the invention can be both a liquid jet recorder and be a beam writer. In the case of the liquid jet recorder are not any control electrodes or collecting devices required for liquid not used for recording.

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The jet recorder according to the invention is suitable, for example, for recording an image stored on the charge storage device of a charge storage type cathode ray tube. He is suitable can also be used to record an image stored in digital form in a matrix memory.

Further advantages and details of the invention emerge from the following description of exemplary embodiments based on the drawing in conjunction with the subclaims. Show it:

1 shows a schematic illustration to explain the concept of the invention,

FIG. 2 curves for explaining FIG. 1,

3 shows a circuit arrangement for controlling a writing system, in which the concept of the invention is applied,

4 curves to explain another implementation of the concept of the invention,

FIG. 5 shows a circuit arrangement on which the curves according to FIG. 4 are based.

In Fig. 1, a recording medium 1 is shown, which is transported from a roller 2 to a roller 3, which by an electric motor 3 'is driven. Across the width of the recording medium 1, which can be, for example, a paper tape, an image is recorded which is generated by a writing nozzle 4 a fine jet 5 of a writing fluid is directed onto the recording medium 1. The nozzle 4 is perpendicular to the Movement direction of the recording medium 1 can be moved by an adjusting device 6, which is controlled by a voltage on the

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Inputs 7 is controlled. The nozzle 4 receives ink from an ink reservoir 9 through a line 8 Line 8 and the reservoir 9 is an ink pump 10 and a pressure regulator 11, which for a constant ink pressure in the line 8 and thus a uniform jet of liquid 5 ensures.

An image is recorded line by line on the recording medium 1 by the liquid jet 5. This record can take place, for example, with continuous transport of the recording medium 1. The lines of the recorded image then do not run exactly at right angles to the recording medium 1. An intensity modulation of the recorded lines is carried out according to the invention in that the speed, with which the liquid jet 5 is moved perpendicular to the direction of movement of the recording medium 1, is changed. If this speed is high, the intensity of the recorded lines is small, if it is small, the intensity is great. In the context of the invention it is possible to move the liquid jet so quickly with respect to the recording medium to move that the writing no longer emerges at all. It is also possible to adjust the speed at which the liquid jet is moved to reduce it so far that further reduction does not increase the intensity (e.g. blackening) more is possible.

The control signal for the. Deflection of the nozzle 4 and the liquid jet 5 can be queried in an advantageous manner from an electrical memory in which the to be recorded Image is stored in digital or analog form.

In Fig. 2, line 12 represents the length and direction of a recorded line. Line 13 shows one example Course of the intensity to be recorded, the line 14 the intensity-modulated writing and the curve 15 the Course of the distance covered by the beam as a function of

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of the time »The distance is plotted on the ordinate 16 and the time on the abscissa 17. Finally indicates line 18 indicates the jet return.

From the curve 15 it is clear that when a recording should take place with high intensity, the distance covered by the beam per unit of time must be small, while then, if the recorded intensity is to be small, the beam moves over the record carrier at high speed will.

In the case of analog speed modulation according to curve 13 in FIG. 2, the respective speed must be adapted to the time that the beam needs to complete a deflection, i.e. to write an image line.

The image to be written can, for example, be an electrical charge distribution on the inside of the screen of a cathode ray tube of the charge storage type, a so-called scan converter, are present. Such a cathode ray tube 20 is shown in FIG. The electron beam 21 of this tube is scanned the charge on a screen 22 line by line. The electron beam 21 is controlled by schematically indicated Deflection plates 23. A curve is shown on the screen which corresponds to curve 13 in FIG. 2 and for the one just scanned Line shows the charge distribution.

At the output 24 of the cathode ray tube 20 is an electrical Tapped voltage that corresponds to the respective scanned charge. The output of the cathode ray tube 20 controls a constant current generator 25, which charges a capacitor 26 with the highest charging speed for so long, how the output 24 has zero potential. At the beginning of the search swing occurs when a charge is scanned at the exit 24 a negative voltage, which makes the transistor 27 conductive and thus the charging speed of the capacitor 26 decreased. The more negative the voltage at output 24,

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the greater the reduction in the charge on the capacitor 26. The voltage across the capacitor 26, i.e. at the output 28 of the circuit arrangement, therefore runs according to curve 15 in FIG. 2 and can be used to control the writing system of the inputs the adjusting device 6 (Fig. 1) are supplied.

The Fig. 4 again shows the lines or curves 12, 13 * 14 and 15. In FIG. 4, a step curve 29 is drawn which indicates that each image line is divided into twelve intensity levels and that each intensity level is two steps of the liquid jet assigned. All steps of the liquid jet are the same. So the jet of liquid makes up twenty-four steps to complete a rash. the The pauses between the second and third step and between the third and fourth are the same size. Also the. Breaks between, the fourth and fifth step and the fifth and sixth step are the same size, etc. The control of the writing system takes place in this case by a pulse generator, which delivers pulses of constant amplitude but different duration. The duration of these impulses corresponds to the pauses after the steps of the liquid jet. The longer these breaks are the greater the intensity of the recorded image point. The pulse duration is made dependent on the desired intensity. This principle is particularly suitable for playback from images stored in digital storage. The control of the electron beam can be done step by step increasing tension. After reaching a predetermined number of steps, "namely twenty-four Steps, the beam will be according to the line 16 again is directed back to its zero point and a new recording begins 30. A new recording can also be made after a given pause. In this case, i.e. if there is no information, the new recording should be started the light beam is extinguished or the liquid jet is blocked and the paper transport is interrupted.

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In principle, it is also possible to use only one step of the liquid jet for each intensity level, i.e. the Deflect the jet of liquid over the recording medium in 12 steps. Each pixel information is therefore in this Fall embodied by a step of the liquid jet. Using multiple steps for each pixel information however, it has the advantage that there is a very uniform intensity modulation.

In the context of the invention, it is also possible to use a to obtain analog deflection according to curve 15. To do this, you can use the from memory, ζ Β. a shift register, core memory or the like, queried signals to a digital-to-analog converter which modulates the speed of the beam transmitter. In this case, if the analog voltage is the When the deflection limit of the beam transmitter has been reached, it is returned to the starting position and a new deflection begins. This process sets an analog comparison between the resulting speed distribution and an analog setpoint signal, which runs according to curve 15, ahead and. requires a complex circuit. The intensity modulation described with the aid of curve 29 is simpler in terms of circuitry to realize.

Fig. 5 shows an embodiment for realizing the idea, which the curve 29 is based on. The image on a recording medium 31 moving in the direction of arrow 32 is generated by a liquid jet 33 whose adjustment system 3 ^ · is controlled by a digital-to-analog converter 35. The input signal of the digital-to-analog converter 35 is supplied by a pulse counter 36, the input of which receives the pulses of a Pulse generator 37 are supplied. The pulse generator 37 is generated by the queried information from a digital memory 38 controlled, in which the image information corresponding to the image subdivision into pixels lying in image lines in digital

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Shape are saved. The image memory 38 is interrogated step by step by a control signal generator 39, i.e. the pixel information successive pixels are fed to the pulse generator 37. The pulse generator 37 delivers Pulses of constant amplitude. For each pixel, however, it delivers a pulse, the duration of which depends on the requested pixel information depends and modulates the intensity of the recorded lines in the manner described in connection with FIG. The control signal generator 39 synchronizes the generation of pulses with the interrogation of the image memory 38 and the count the pulses in the pulse counter 3'6.

The pulse counter 36 operates after a predetermined number of times of pulses - in the example after 24 pulses - the deletion of all components, i.e. the return to the initial state and thus also the return of the write beam according to the line in FIG. 4.

The "method according to Figure 4 and 5 is particularly suitable for Output of computer-generated images, maps and figures. It is also suitable for the output of ultrasonic signals, wherein the ultrasonic signal is stored and sampled according to the idea of the invention.

By means of the circuit arrangement according to FIG. 3, a standing television picture can also be written. A television picture usually exists from 312 + 313 lines with a search time of 64 / usec each including the retrace time of the electron beam. In these 64 / usec, the changes in intensity - the so-called video information - of an image line can be stored in an electronic memory are stored, an intensity distribution corresponding to FIG. 4, namely the curve 13 for each image line receives. Immediately thereafter, the speed-modulated deflection of the write beam according to curve 29 in FIG. 4 can take place. After the end of the deflection and expediently during the jet return, the memory content is deleted and

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through the information for the adjacent line on the screen replaced. To do this, synchronization must take place in such a way that the time between two write swings is the same the time of 312 + 313 + 1 line excursions on the screen or a multiple thereof.

Another application example of the inventive concept is the recording of power density spectra, for example in the analysis of electroencephalograms (EEG). The power density spectra of an EEG signal are here in constant Time intervals of the order of 10 seconds are calculated. According to the invention, a completely calculated spectrum can be stored in an electrical memory in accordance with curve 13 in FIG. 4 and written immediately after curve 29 in FIG. 4, the frequency being 0 Hz of the spectrum am The beginning of the deflection and the highest frequency - e.g. 20 Hz - is at the end of the deflection.

The invention also allows reference lines, for example for certain frequencies - 0, 5, 10, 15, 20 Hz when recording of the power density spectrum described - to be recorded. This can be done, for example, by the pulse generator 37 in FIG. 5 after a corresponding number of pulses - controlled by the counter 36 - extremely long or extremely short Emits pulses. After each full deflection, the memory content is replaced by a new spectrum next to the previous one is written at a distance that is in the order of magnitude of the line width (e.g. 0.3 mm). In this way you can Write the analysis of an EEG, for example the recording of a night, on a length of about 1 m of the recording medium.

Within the scope of the invention, in FIG. 1 the recording medium 1 can also be moved step by step, in such a way that a synchronizing device controls the transport of the recording medium one step after completing one line recording

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The step length is chosen so that the spaces between between the lines are also in the order of magnitude of the line width. Even with continuous movement the speed of the recording medium 1 is selected so that the spaces between two lines in this Order of magnitude.

It is advisable to switch off the writing beam when it returns after it has reached its full deflection. For this purpose, e.g. the Pulse counter 36 in Fig. 5 can be used.

The invention is in connection with a liquid jet recorder described. In the context of the invention, the beam transmitter can also be a light beam transmitter that has a constant, directs a thin light beam onto a light-sensitive recording medium.

In the context of the invention, a fast write beam return (FIGS. Z and 4) can be dispensed with. The speed of the write beam can therefore be modulated in both directions of movement of the beam transmitter »

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Claims (16)

■ Claims MJ beam recorder with a beam transmitter that emits a writing beam directed at a recording medium, with means for generating a relative movement between the beam transmitter and the recording medium in two directions lying approximately perpendicular to one another in the sense of line-by-line image recording and with a modulation device for the intensity of the recorded lines, characterized in that the beam transmitter (4) has a write beam (5, 33) constant strength for recording to the recording medium (1, 31) sends and that the modulation device (Fig. 3, 5) a Device for changing the relative speed between the beam transmitter (4) and the recording medium (5, 33) in at least ' one direction is such that for an increase in intensity a decrease and for an intensity decrease an increase the speed takes place. 2. Writer according to claim 1, characterized in that the beam transmitter (4) is approximately perpendicular to the direction of movement The recording medium (5, 33) can be deflected in an oscillating manner over the writing width. 3. Writer according to claim 2, characterized in that the recording medium (5, 33) by a feed device (2, 3) is continuously moved in one direction and the feed rate is chosen so that the gaps between the lines are in the order of magnitude of the line width. 4. Writer according to claim 2, characterized in that a feed device (2, 3) for the recording medium (1, 33) is present, which causes a step-by-step movement of the recording medium (1, 33) that the feed device -12- 509885/1213. tion (2, 3) and the deflection device (6, 34) for the beam transmitter are connected to a synchronizing device that controls the transport of the recording medium (1) by one step Causes completion of the recording of a line and that the step length is chosen so that the spaces between the lines are in the order of magnitude of the line width. 5. Writer according to one of claims 2 to 4, characterized in that that means (36) for switching off the write beam in a direction of movement (return) of the beam transmitter available. 6. Writer according to one of claims 1 to 5, characterized in that that the modulation device (Fig. 3, 5) contains a voltage generator (20, 35) ", the one the respective relative speed provides embodied electrical tension. 7. Writer according to claim 6, characterized in that the voltage generator is a cathode ray tube (20) from the charge Contains storage type. 8. pen according to claim 7, characterized in that a capacitor (26) is present, which is charged with a current which corresponds to the respectively scanned charge of the charge store (22) of the cathode ray tube (20) and on from which the voltage that embodies the respective relative speed is tapped. 9. pen according to claim 6, characterized in that the voltage generator is a digital-to-analog converter (35) whose input contains the digital speed signals (image signals) queried from a memory (38) « -13- 509885/1213 ./13 10. Writer according to one of claims 1 to 5, characterized in that that the modulation device has a pulse generator (37) for generating adjustment pulses for the beam transmitter (4) or the transport system (2, 3) of the recording medium (1) for line recording contains the same amplitude whose duration corresponds to the intensity of the corresponding image points and whose number per picture line is the desired Image resolution is selected accordingly. 11. Writer according to claim 10, characterized in that the pulse generator (37) is controlled by a digital memory (38) which is built up according to the image subdivision into image points lying in image lines and is queried. 12. Writer according to claim 10 or 11, characterized in that the pulse generator (37) is assigned a pulse counter (36) is that the return of the adjustable system in a starting position for line recording after a predetermined Number of output pulses of the pulse generator causes. 13. Writer according to one of claims 1 to 12, characterized characterized in that the jet transmitter contains a nozzle (4) which for recording a constant, thin liquid jet (5) is aimed at the recording medium (1). 14. Writer according to one of claims 1 to 12, characterized characterized in that the beam transmitter is a light beam transmitter which sends a constant, thin beam of light onto the photosensitive Record carrier sets up. 15 »Writer according to one of claims 1 to 14, that means for interrupting the paper transport and for switching off the Write beam (5) are available in the absence of information. -14- 509885/1213 16. Writer according to claim 2, characterized in that the modulation device controls the speed of the write beam (5) modulated in both directions of movement of the beam transmitter. 509885/1213 Blank page