US2000014A

US2000014A - Telautograph

Info

Publication number: US2000014A
Application number: US614347A
Authority: US
Inventors: Mont Allen B Du
Original assignee: Individual
Current assignee: Individual
Priority date: 1932-05-31
Filing date: 1932-05-31
Publication date: 1935-05-07
Anticipated expiration: 1952-05-07

Description

y 1935- A. B. DU MONT 2,000,014

TELAUTOGRAPH Filed May 31, 1932 mm b W com'nc'r wosmou INVENTOR HIS ATTORNEY Patented; May 7, 1935 UNITED STATES PATENT orrlcl:

'TELAUTOGRAPH Allen B. Du Mont, Upper Montclair, N. J.

Application May 31, 1932, Serial No. 614,347

7 Claims.

This invention relates to improved means whereby the movements of a body such as a pen, pencil or the like, in tracing a picture, writing or in other uses, may be reproduced. This is now done by an instrument known as the telautograph wherein the movements of a stylus such as a pen, pencil or the like is moved to trace the desired writing or characters and this is reproduced at a distant station by means of a pantograph operated pencil marking upon a sheet of paper which is slowly moved beneath the pencil.

It is the main object of the present invention to provide improved means for transmitting writing, pictures and the like which shall be simple and eflicient and require few, if any, moving parts in the receiver.

To the end as stated, it is a further object of the invention to provide a system of the chareffected by the shifting of cathode rays in response to the movements of the stylus at the transmitter and rendering the said rays manifest in their various positions.

A further object of the invention is to provide a telautograph system which is well adapted to have communication between the transmitter and receiver accomplished by radio which would be particularly valuable for aeroplane scouting in time of war.

It is a further object of the invention to provide a telautographic system wherein a photographic record of the message may be readily made.

Other and ancillary objects of the invention will appear hereinafter.

In the accompanying drawing which illustrates the invention- Fig. l is a diagrammatic view showing a telautographic system embodying the invention, the cathode ray tube at the receiving end being shown in section;

Fig. 2 is a diagrammatic view of the screen end of the cathode ray tube illustrating in diagram the positions assumed by the light spots on the cathode ray screen occasioned by the transmission of a character;

Fig. 3 is an edge view of the resistance blocks of the transmitter;

Fig. 4 is a graphical representation of the variation in potential across the resistance of the transmitter;

Fig. 5 is a section on the line 5--5 of Fig. 1;

and

55 Fig. 6 is a section on the line 6-6 of Fig. 1;

acter referred to wherein the reproduction is- Referring to the drawing, the apparatus at the receiving end of the system comprises a cathode ray tube including a suitably evacuated glass envelope I, provided with a suitable electron emitting filament 2 energized from a transformer secondary 3, a focusing electrode 4 which is preferably kept at a slightly negative potential with relation to the filament as by means of a battery 5 having its negative terminal connected with the electrode 4 and its positive terminal con- 10 nected with the center of the transformer secondary 3. The reason for maintaining the electrode at a slightly negative potential as stated is to prevent positive ion bombardment of the filament and to focus the rays.

The cathode ray tube is also provided with the tubular accelerating electrode 6 which is maintained positive by direct current source illustrated by the battery I. This source may be from 200 to 400 volts and has its negative terminal connected with the central point of the secondary 3 of the transformer and its positive terminal with the accelerating electrode 6. The beam of cathode rays thus projected impinges upon a fluorescent and phosporescent screen 8 of calcium fluoride which is supported upon the interior of the end of the glass envelope l.

About the path of the cathode rays are arranged two pairs of deflection plates 9 and In for the rays, the plates of the pair 9 being on oppcsite sides of the ray path and the pair of plates I0 are below and at substantially 90 from the pair 9, and the plates of the pair ID are also on opposite sides of the path of the rays.

In receiving the message the rays are shifted in response to the transmitting apparatus which will now be described, and which may be located at any desired distance from the receiving apparatus and related thereto in any suitable way as by electric conductors, radio, etc.

A block or plate of carbon H or other suitable resistance material has secured to its edges copper strips 12 and [3 which are substantially coextensive with the carbon plate. One side of the carbon plate is connected through the copper strip l3 and conductor M with the negative terminal of a suitable source of current I5 representedas a battery, the plus terminal of the battery being connected through the conductor l6 and the copper strip [2 with the opposite edge of the carbon plate II. The carbon plate H thus acts as a potentiometer resistance for varying the potential applied to the deflection plates H] by connection as will be hereinafter referred to.

Lying alongside the carbon plate I I is a similar e the contact 3| is moved parallel to the strips |2 carbon plate I! having secured to its edges and co-extensive therewith the copper strips l6 and 9, these strips being at the top and bottom of the plate while the strips l2 and I3 are at the sides of the plate II, in other words are 90 removed from the strips J9 and I9. The plate I! has the strip l6 on one side connected by a conductor 26 with the negative terminal of a suitable source of electro-motive force shown as the battery 2|, the other terminal of the battery being connected by the conductor 22 with the copper strip |9 at the opposite edge of the carbon plate II. The carbon plate I! therefore acts as a potentiometer resistance across the source 2| whereby the potential between the plates 9 may be varied, the connections for accomplishing which will be presently set forth.

The strip I3 is connected by a conductor 23 with one of the cathode ray deflection plates I. The other one of the deflection plates III is connected by a conductor 24 with a contact 25 engaging with the surface of the carbon plate H and adapted to have its contact therewith shifted to various portions thereof. This contact is mounted upon the end of an arm 26 of a well known pantograph arrangement comprising the

pivoted arms

21, 28 and 29, the arm 28 having the fixed pivot 36. The link 21 is pivoted to the

arms

26 and 29, the arm ,29 being pivoted at its other end to the link 28 which is pivoted at one end to the extremity of the arm 26 and at its other end to the stationary pivot 36. At the pivoted junction of the

arms

21 and 29 is'a holder for a stylus such as a pen or pencil.

Also mounted upon the extremity of the arm 26 is another contact 3| contacting the plate H, at any instant, at a point directly opposite the engagement of the contact 25 with the plate The

contacts

25 and 3| and other conductors are insulated from each other and the contact 3| is connected by a conductor 32 with one of the plates of the pair 9, the other plate of that pair being connected by the conductor 33 with the conductor 20 leading to-the copper strip H3 at the edge of the carbon plate II.

It will now be seen that when the stylus or pen 34 is moved, the upper extremity of the arm 26 carrying the

contacts

25 and 3| will be correspondingly moved. It will further be apparent that when the pen is moved in a line parallel to the strips l2 and I3, the amount of resistance in the plate II which is included between the strip l3 and the contact 25 will not be changed and hence the potential between the plates III will not be changed. Movement of the contact 25 in a direction perpendicular to that just stated will, however, cause a change in the amount of resistance of the plate I I included between the strip l3 and contact 25 and therefore a change in the potential between the plates II). This potential will depend upon the position of the contact 25, the potential or volts being illustrated in the graph of Fig. 4 from which it clearly appears that the maximum potential of voltage impressed upon the plates M will be when the contact 25 is substantially at the side of the plate II at which is located the strip l2, and that this impressed potential will decrease proportionately as the contact 25 is moved across the plate between the strips l2 and I3 and will be zero when the contact 25 is substantially at the side of the plate where is located the strip l3.

Similarly the graph of Fig. 4 indicates the gradient of potential impressed upon the plates 9 as maximum when the contact 3| 4 and I3, being a is substantially in engagement with the strip l9 and a minimum when the contact 3| is at the opposite edge of the plate II. There is no change in the potential impressed upon the plates 9 as the contact 3| is moved in a direction parallel to the strips I6 and I9. 1

It will now be apparent that movement of the pen 24 in a vertical direction parallel to the strips l2 and I! will cause a variation in the potential difference between the plates 9 but will not vary the potential between the plates l6 whereupon the cathode ray will be deflected in one plane. Similarly movement of the pen horizontally will cause a similar movement of the contact end of the arm 26 which will result in variation of the potential between the plates l6 while the potential across the plates 9 will not be changed. The cathode ray beam will therefore be deflected or shifted in a plane at right angles to the aforementioned plane of shifting. Should the pen be moved in any intermediate direction, that is in a direction having tical component the potential between the plates 9 will be varied according to the vertical component and the potential across the plates III will be varied according to the horizontal component of the movement, and the cathode ray beam will be deflected accordingly.

It will now be apparent that the cathode beam will be deflected according to the movement of the pen so that the spot of light produced on the screen 8 by bombardment of the electrons of the beam will be moved in a path corresponding to the path in which the pen 3! is moved so that when the pen is moved to outline letters, writing, pictures or the like, the spot will be moved correspondingly to trace the writing, letters, or pictures by means of the spot of light upon the screen.

The calcium fluoride of the screen has the property that after having been caused to fluoresce by bombardment of the cathode ray beam,

which will take place promptly upon the application of the beam, the luminosity will remain for a considerable time after the removalof the beam from the spot, say thirty seconds. This retention or persistence of the luminosity after withdrawal of the beam is commonly referred to as phosphorescence and it is in this sense that the term phosphorescence is used herein.

In order that a larger portion of the screen may be available for the writing, picture or the like, two pairs of

coils

35 and 36 are placed at right angles to each other and about the path of the cathode beam, which are constantly excited so that the beam is shifted from the central axis of the tube (A', Fig. 2) to a point X which represents the position of the axis of the beam i. e. the spot of light on the screen when the deflecting plates 9 and III are exercising no deflection. When the beam is not thus shifted but its axis is at A, but one fourth of the area of the screen is available for the writing.

It now the contact end of the arm 26 is at the point A (at which point thereis a potential of approximately 56 volts applied to each pair of plates 9 and ID) the cathode beam will be deflected and the light spot caused thereby upon the fluorescent screen 8 will appear at A, the center of the screen (see Fig. 2). If the pen 34 is moved in a vertical line so that the contact end of the arm 26 is moved from the position A to the position B, the potential across the deflection plates 9 will be changed to say volts,

both a horizontal and verwhile the potential across the deflection plates It] remains as before. The cathode beam will therefore be deflected so that the fluorescent spot on the screen will move from A to B (see Fig. 2).

If now the pen 34 is moved laterally so that the

contacts

25 and 3| move to the position C, the potential across the plates 9 remains as before while that across the plates I0 is reduced to say 20 volts which causes a deflection of the cathode beam in a plane at right angles to its previous deflection and its spot of light on the fluorescent screen will move at right angles to the line A and B, to the spot C.

It will now be seen that the light spot in moving from A to B and from B to C has traced the letter L and as the luminosity persists for some time after the passage of the cathode beam, the entire letter L will appear in lines of light which will remain visible until the luminosity fades away. Similarly other letters, words or pictures might be traced upon a fluorescent screen in obedience to the movements of the pen 34. The persistence of vision of the human eye is not for a suflicient length of time to provide a character outline as indicated. It will be observed that the phosphorescence is for a much longer period than the persistence of vision of the human eye, so that the outlining of the letters, words of pictures may be accomplished as described.

It will be apparent that the flgure or letter traced upon the screen may be permanently recorded by photographing it upon a photographic fllm in a manner as is well understood in connection with the photographing of similar outlines in oscillographs.

While the invention has been illustrated in what is considered its best application it may have other embodiments without departing from its spirit and is not therefore limited to the structure shown in the drawing.

What I claim is:

1. The combination with means for generating cathode rays, of a fluorescent and phosphorescent screen and means angularly displaced about the path of said rays for relatively deflecting said rays and screen, a pair of plates of resistance material respectively controlling angularly displaced ray deflecting means by respectively varying the potentials applied thereto, contacts between said plates and respectively bearing against the same and adapted to be moved in any direction between said plates, said contacts being mechanically secured together but insulated from each other and means for electrically connecting said contacts with ray deflecting means angularly displaced about .the ray path and means for impressing potentials respectively upon the angu-' larly displaced ray deflecting means.

2. The combination with means for generating cathode rays, of a fluorescent and phosphorescent screen and means angularly displaced about the path of said rays for relatively deflecting said rays and screen, a pair of plates of resistance material respectively controlling angularly displaced ray deflecting means by respectively varying the potentials applied thereto, contacts between said plates and respectively bearing against the same and adapted to be moved in any direction between said plates, said contacts being mechanically secured together but insulated from each other and means for electrically connecting said contacts with ray deflecting means angularly displaced about the ray path and means for impressing potentials respectively upon the angularly displaced ray deflecting means, a stylus and a pantograph connection between said contacts and said stylus.

3. The combination with means for generating cath'ode rays, of means for rendering said rays manifest comprising a screen of calcium fluoride.

4. The combination with means for generating cathode rays, of means for rendering said rays manifest comprising a fluorescent and phosphorescent material retaining phosphorescence after the removal of the cathode rays from action uponit, for a greater time than that of the persistance of vision of the human eye and means for relatively deflecting said rays and manifesting means.

5. The combination with means for generating cathode rays, of means for rendering said rays manifest comprising a'screen of calcium fluoride and means for relatively deflecting said rays and manifesting means at will.

6. The combination with means for generating cathode rays, of means for rendering said rays manifest comprising a screen of calcium fluoride, a movable body and means for relatively deflecting said rays and manifesting means responsive to the movement of said body.

7. In a telautograph the combination with means for producing a beam of cathode rays, of a fluorescent and phosphorescent screen for receiving said beam and means for shifting said beam with relation to said screen in a plurality of directions at angles with each other, a stylus, and means operatively relating said stylus to said beam shifting means whereby the spot of impingement of said beam on said screen follows the movement of said stylus, the material of said screen being adapted to retain phosphorescence during successive shifted positions of said impingement spot suflicient to form a luminous line outlining a predetermined character or symbol.

ALLEN B. DU MONT. 1