US2204427A - Synchronizing method - Google Patents
Synchronizing method Download PDFInfo
- Publication number
- US2204427A US2204427A US72393A US7239336A US2204427A US 2204427 A US2204427 A US 2204427A US 72393 A US72393 A US 72393A US 7239336 A US7239336 A US 7239336A US 2204427 A US2204427 A US 2204427A
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- Prior art keywords
- image
- light
- synchronizing
- supplementary
- amplitude
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N5/00—Details of television systems
- H04N5/04—Synchronising
- H04N5/06—Generation of synchronising signals
- H04N5/067—Arrangements or circuits at the transmitter end
- H04N5/0675—Arrangements or circuits at the transmitter end for mixing the synchronising signals with the picture signal or mutually
Definitions
- two or more photo-electric cells have hitherto been used connected in opposition relation and of which one delivered, 6. g., positive image impulses while the other produced. e. g., negative impulses by being correspondingly illuminated durlngthe occurrence of the line or image gaps.
- the impulses of the various photo'- electric cells were thereupon, after being suitably amplified, combined and produced an oscillation from which the synchronizing signal could read-.
- Fig. 1 shows the scanning area of a light ray scanning transmitter.
- Fig. 3 shows an optical system which for, example may' be used for linear scanning of an image in accordance with the invention by means of 5 a periorated circular disk.
- Fig. 4 illustrates a modification of the invention in which an image pick-up tube of the mosaic screen type is employed.
- the supplementary illumination is produced for example by means of a separate light source which so illuminates a surface lying outside the scanned field that the reflected light passes into the pho- 1o to-electric cell.
- a strip 2 may be disposed above or adjacent the surface I tra, versed by the point of light (see Fig. 1) and illuminated rhythmically by the movement of'the light ray.
- this invariable supplementary illumination produces a constant basic current in the photo-electriccell, on which the image impulses are superimposed.
- the supplementary light is obturated between the lines and/or the images, so that synchronizing impulses are created, the amplitude of which are smaller than those 01' the darkest portion of the image. In this manner the wave shape of the image and synchronizing signals shown in'Fig. 2 is obtained.
- nal for a fraction of a line is equal to zero and succeeding images it amounts to the. duration of severallines.
- Line impulses which are indicated by z and image alternation impulses indicated by "b (Fig. 2) are thus produced.
- the zero line may be so displaced that it becomes for example as high as amplitude 3; for this purpose the initial voltage is chosen to correspond with the amplitude pr **d by the supplementary illumination.
- Syncc chronizing slgnals are thus obtained, the algebraic sign of which is opposite that of the image signal.
- the arrangement used for interrupting the supplementary light is preferably formed of a diaphragm device and iscoupled with the device used for producing the movement of the light ray (e. g., a perforated disk or a mirror wheel) so that the synchronizing impulse always'retains the correct phase relation with respect to the image impulse.
- the device used for producing the movement of the light ray e. g., a perforated disk or a mirror wheel
- a uniform general illumination of the whole scanned surface may be used which is likewise interrupted in relation with the line frequency and the image alternati'on frequency.
- the photoelectric cell 1'6 is located behind. the perforated disk l5.
- a rotating diaphragm I1 is provided in the embodiment under discussion which is positively coupled with the perforated disk.
- the diaphragm H has a transparent portion l8 in the form of an annular strip interrupted at one point and is otherwise opaque.
- the width 19 of strip I8 is so proportioned that it is somewhat less than the distance 20 of two adjacent holes in the perforated disk.
- the supplementary light thus passes through dur ing the production of the image signal, but upon thetransition from one line to the succeeding one a short complete obturation occurs in order to create the synchronizing impulse for the line frequency.
- the image alternation impulse b (Fig. 2) is produced in the form of a longer dark period; during this period is produced, in addition to obturation of the image light, a prolonged obturation'of the supplementary light by the part 2
- a 240 line 7 picture will be produced.
- the obturating diaphragm disk I1 is then allowed to run at 1500 R. P. M. and the image alternation impulses will be lcibltained for each fourth rotation of perforated dis 5.
- the obturation may also be effected by an oscillating or intermittently moved diaphragm.
- an independent light source may be used, the light of which falls on the photoelectric cell during the production of the image impulse.
- the light of this source may likewise be controlled by a diaphragm or an intermittent light source may be used which only emits light during the production of the image impulse.
- the supplementary illumination from the light source 22 is preferably so arranged that the image screen 23 .of the cathode ray tube 24 attains a uniform supplementary illumination.
- the interruption of the supplementary illumination in cadence with the line or image alternation frequency is not effected by interrupting the light but rather by allowing a This permits retaining the advantage accruing from the use of a cathode ray type of image pickup tube wherein no movable elements are required, and this also has the further advantage that separately produced synchronizing signals need not later be first combined with the image impulses but rather that the oscillations to be transmitted have the correct form at the outset.
- a television transmitter utilizing a cathode ray scanning tube containing a mosaic of photoemissive cells upon which the optical image is directed
- the method of producing a synchronizing pulse which comprises directing in addition to said optical image an unmodulated light beam uniformly over all of said screen except one edge thereof scanning said mosaic with a cathode ray beam of elemental cross-section, and utilizing the difference in signal strength occurring when the edge portion of said mosaic not under illumination by said unmodulated light beam is scanned at this point by said beam to produce said synchronizing pulse;
Description
June 11, 1940. i 'RMGLLER 2,204,427
SYNCHRONIZING METHOD Filed A 'ri 2, 1956 Patented June 11 1940 PATENT orries 2,204,421 srncnaomzmc r'm'mon Rolf Miller, zehlendorf, near Berlin, Germany,
asslgnor to the ill-n1 of Fernseh Aktien-Gesellschatt, Zehlendorf, near Berlin, Germany Application April 2, 1936, Serial No. 72,393
In Germany April 10, 1935 r 1 Claim.
10 an amplitude exceeding that of the image imv pulses or to keep the amplitude zero, or to use an amplitude of algebraic sign opposite to that of the image impulse, so as to'effect separation of the synchronizing signal from the image signals in an unobjectionable manner at the receiving end.
In order to produce synchronizing signals which extend from the zero line to the opposite side of the image signals or in which the amplitude is equalto zero, two or more photo-electric cells have hitherto been used connected in opposition relation and of which one delivered, 6. g., positive image impulses while the other produced. e. g., negative impulses by being correspondingly illuminated durlngthe occurrence of the line or image gaps. The impulses of the various photo'- electric cells were thereupon, after being suitably amplified, combined and produced an oscillation from which the synchronizing signal could read-.
ily be separated at the receiving. end from the image signals, for example, by means of amplitude filters.
In accordance with the present invention the production of the synchronizing impulse or the 5 oscillation composed of the image impulses and the synchronizing impulses is simplified by eliminating the use of supplementary photo-electric cells and succeeding amplifiers. In accordance with the invention this is achieved by-providing 40 supplementary illumination of constant value for the photo-emissive surface of the image pick-up tube which, however, is only effective during the duration of the image signals and which is ineffective during the period of the synchronizing impulse. U I 1 The invention is described in conjunction with the examples illustrated.
Fig. 1 shows the scanning area of a light ray scanning transmitter.
Fig. 2 is a diagrammaticrepresentation of the course of the image and synchronizing signals.
Fig. 3 shows an optical system which for, example may' be used for linear scanning of an image in accordance with the invention by means of 5 a periorated circular disk.
Fig. 4 illustrates a modification of the invention in which an image pick-up tube of the mosaic screen type is employed.
Fig. 5 is aview of the perforated circular disk with one of its cooperating rotating diaphragms.
In using a light ray scanning transmitter, the supplementary illumination is produced for example by means of a separate light source which so illuminates a surface lying outside the scanned field that the reflected light passes into the pho- 1o to-electric cell. 'For this purpose a strip 2 may be disposed above or adjacent the surface I tra, versed by the point of light (see Fig. 1) and illuminated rhythmically by the movement of'the light ray. During the scanning movement of the 15 light ray this invariable supplementary illumination produces a constant basic current in the photo-electriccell, on which the image impulses are superimposed. The supplementary light is obturated between the lines and/or the images, so that synchronizing impulses are created, the amplitude of which are smaller than those 01' the darkest portion of the image. In this manner the wave shape of the image and synchronizing signals shown in'Fig. 2 is obtained.
If the image light and the supplementary light are obturated by a diaphragm, the resulting signal has zero amplitude. As soon as the supplementary illumination is turned on, but while the image per. se is black, the photo-electric cell delivers a signal of the amplitude indicated by! in Fig. 2." The lighter and more transparent portions of the image are produced by the amplitude indicated by 4 in Fig. 2. In this manner a signal is produced in which the synchronizing m impulse is furnished by a zero value of the-cure rent or a carrier wave. The durationof obturation of the supplementary light as well as that of the image light is preferably so chosen that between successive lines the amplitude of the sig- M? nal for a fraction of a line is equal to zero and succeeding images it amounts to the. duration of severallines. Line impulses which are indicated by z and image alternation impulses indicated by "b (Fig. 2) are thus produced. By suitably choosing an initial voltage the zero line may be so displaced that it becomes for example as high as amplitude 3; for this purpose the initial voltage is chosen to correspond with the amplitude pr duced by the supplementary illumination. Syncc chronizing slgnals are thus obtained, the algebraic sign of which is opposite that of the image signal.
The arrangement used for interrupting the supplementary light is preferably formed of a diaphragm device and iscoupled with the device used for producing the movement of the light ray (e. g., a perforated disk or a mirror wheel) so that the synchronizing impulse always'retains the correct phase relation with respect to the image impulse.
In lieu of supplementary illumination exterior to the field scanned by the light ray, a uniform general illumination of the whole scanned surface may be used which is likewise interrupted in relation with the line frequency and the image alternati'on frequency.
The device shown in Figs. 3 and 5 for line scanning of a film uses a light source 5 by means of lenses [3 and I4 and passes to the perforated disk 15. The unmodulated light which originates w from mirror 8 likewise passes through lens M,
after striking mirror II and is thrown onto the perforated disk where it supplies the supplementary illumination. The photoelectric cell 1'6 is located behind. the perforated disk l5.
In order to render the supplementary illumination ineffective at the required instant, a rotating diaphragm I1 is provided in the embodiment under discussion which is positively coupled with the perforated disk. The diaphragm H has a transparent portion l8 in the form of an annular strip interrupted at one point and is otherwise opaque. The width 19 of strip I8 is so proportioned that it is somewhat less than the distance 20 of two adjacent holes in the perforated disk.
' The supplementary light thus passes through dur ing the production of the image signal, but upon thetransition from one line to the succeeding one a short complete obturation occurs in order to create the synchronizing impulse for the line frequency. After a given number of lines, required by the analyzing system have been covered, as by the travel of the given number of holes of the perforated disk, the image alternation impulse b (Fig. 2) is produced in the form of a longer dark period; during this period is produced, in addition to obturation of the image light, a prolonged obturation'of the supplementary light by the part 2| of the diaphragm. If, for example, the perforated disk has 60 holes, and a speed of 6000 R. P. M. then, at 25 images per second, a 240 line 7 picture will be produced. The obturating diaphragm disk I1 is then allowed to run at 1500 R. P. M. and the image alternation impulses will be lcibltained for each fourth rotation of perforated dis 5.
The obturation may also be effected by an oscillating or intermittently moved diaphragm.
In this case also, an independent light source may be used, the light of which falls on the photoelectric cell during the production of the image impulse. The light of this source may likewise be controlled by a diaphragm or an intermittent light source may be used which only emits light during the production of the image impulse.
When using the arrangement of the invention in a transmitter which cooperates with an electron-ray tube containing a mosaic of photo-emissive cells as illustrated in Fig. 4, the supplementary illumination from the light source 22 is preferably so arranged that the image screen 23 .of the cathode ray tube 24 attains a uniform supplementary illumination. The interruption of the supplementary illumination in cadence with the line or image alternation frequency is not effected by interrupting the light but rather by allowing a This permits retaining the advantage accruing from the use of a cathode ray type of image pickup tube wherein no movable elements are required, and this also has the further advantage that separately produced synchronizing signals need not later be first combined with the image impulses but rather that the oscillations to be transmitted have the correct form at the outset.
I claim:
In a television transmitter utilizing a cathode ray scanning tube containing a mosaic of photoemissive cells upon which the optical image is directed, the method of producing a synchronizing pulse which comprises directing in addition to said optical image an unmodulated light beam uniformly over all of said screen except one edge thereof scanning said mosaic with a cathode ray beam of elemental cross-section, and utilizing the difference in signal strength occurring when the edge portion of said mosaic not under illumination by said unmodulated light beam is scanned at this point by said beam to produce said synchronizing pulse;
M ROLF MOLLER.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE2204427X | 1935-04-10 |
Publications (1)
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US2204427A true US2204427A (en) | 1940-06-11 |
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Family Applications (1)
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US72393A Expired - Lifetime US2204427A (en) | 1935-04-10 | 1936-04-02 | Synchronizing method |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2817702A (en) * | 1951-10-12 | 1957-12-24 | Bell Telephone Labor Inc | Feedback intensity control for continuous film scanner |
US3488433A (en) * | 1965-12-03 | 1970-01-06 | Akai Electric | Video tape recorder employing a delay of the horizontal sync signals to facilitate separation from the video signal |
US3493675A (en) * | 1965-12-11 | 1970-02-03 | Akai Electric | Direct magnetic recording system with accentuation of video synchronizing pulses |
US3601536A (en) * | 1969-01-15 | 1971-08-24 | Ibm | System and method for developing a composite video signal |
US4295155A (en) * | 1979-06-08 | 1981-10-13 | International Telephone And Telegraph Corporation | Gray scale sync video processing system |
-
1936
- 1936-04-02 US US72393A patent/US2204427A/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2817702A (en) * | 1951-10-12 | 1957-12-24 | Bell Telephone Labor Inc | Feedback intensity control for continuous film scanner |
US3488433A (en) * | 1965-12-03 | 1970-01-06 | Akai Electric | Video tape recorder employing a delay of the horizontal sync signals to facilitate separation from the video signal |
US3493675A (en) * | 1965-12-11 | 1970-02-03 | Akai Electric | Direct magnetic recording system with accentuation of video synchronizing pulses |
US3601536A (en) * | 1969-01-15 | 1971-08-24 | Ibm | System and method for developing a composite video signal |
US4295155A (en) * | 1979-06-08 | 1981-10-13 | International Telephone And Telegraph Corporation | Gray scale sync video processing system |
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