US1766644A - Synchronizing system - Google Patents

Description

June 24, 1930. c; F. JENKINS 1.766.644

SYNCHRONIZING SYSTEM Filed July 21. 192'? .3 She ets-sneet l .24, 1930.. .C. F. JENKI 1 SYNCHRONIZING SYSTEM I FiledJuly 21, L927 23-Sheext-s-Sheei 2 June 24, 1930. c. F. JENKINS 1,766.644

SYNCHRONIZING SYSTEM Filed July 21, 1927 5 Sheets-Sheet 3 Patented June 24, 1930 UNITED STATES PATENT OFFICE CHARLES FRANCIS JENKINS, OF WASHINGTON, DISTRICT OF COLUMBIA,

JENKINS LABORATORIES, OF WASHINGTON, DISTRICT OF COLUMBIA,

TION OF THE DISTRICT OF COLUMBIA SYNCHRONIZING SYSTEM Application filed July 21,

This invention relates to picture transmission systems, and in partlcular to ar- 'rangements for maintaining synchronous opmeans for automatically maintaining a provide definite speed relationship between the transmitting and receiving apparatus.

Another object of my invention is to devise novel relay apparatus capable of responding to electric current variations of relatively high frequency.

My inventlon 1s illustrated in the accoman in drawm in which like reference y a g characters represent like parts.

Figure 1 is a diagrammatic showing of one form of my invention employed at the.

receiving station.

Figure 2 is a diagrammatic representation of a second form of apparatus employed at the receiving station. 7

Figure 3 is a third modification of the invention. I

In Figure 1, a drive a cylindrical mounted the surface or film motor M is arranged .to drum C upon which is which is to receive the picture being transmitted. The motor M comprises an armature A and a field winding F, each of which is supplied with; current from the battery B. The armaoutput circuit ture circuit of the motor is completed from battery B through the plifier A3, armature A, and back to battery B. The armature also has a shunt circuit from battery B through resistance R1.

The receiving station is provided with a radio receiving set comprising a detector D1 and an amplifier A1. Connected to the outut circuit of amplifier A1 is a second amplifier A2, the output circuit of which contains an incandescent lamp L. The picture recording apparatus is also connected to the' of amplifier A1 and comprises, for example, a solenoid S arranged to operate an inking pen P. A lens L1 is arranged to gather the divergent rays proceeding from lamp L and focus them upon a lightsensitive cell LS connected in the input ciroutput circuit of am-- nssreuon 'ro HEISSUED 1927. Serial No. 207,515.

cuit of amplifier A3. A disc D, provided with a series of holes arranged around its periphery, is mounted upon the shaft of motor A and is arranged to rotate in the path of the rays of light projected upon lightsensitive cell S by the lens L1. The width of the openings in disc D is preferably equal to half the distance between the openings, although this ratio may be varied considerably is desired.

. The operation of Figure 1 is as follows:

It is to be understood that a radio wave is being transmitted from the transmitting station and that the wave is modulated in accordance with the light variations of successive elementary areas of the picture being transmitted and also in accordance with the speed of rotation of the transmitting apparatus. The synchronizing modulations bear a definite relation to the speed of the transmitting apparatus and may be 'produced in any desired manner, but I prefer to employ a light-chopper for this purpose, as disclosed in my United States Patent No. 1,694,065, granted to C. F. Jenkins, December 4:, 1928. The modulated wave is received at the receiving station and detected by detector D1 to derive therefrom low frequency currents which represent both the picture light variations and the synchronizing impulses. This composite current .is supplied to amplifier A1 where it is amplified and supplied to the output circuit. The amplified current is supplied to the recording apparatus which responds to the picture variations and causes the pen P to record upon the picture receiving surface, mounted upon drum C, ink marks corresponding to the dark portions of the-picture being transmitted. The recording apparatus need not necessarily respond to the synchronizing interruptions or variations. portion of the current in the output circuit of amplifier A1 is supplied to the input circuit of amplifier A2, and lamp L1 is caused to vary inintensity in accordance with the current variations. Accordingly, the beam of light falling upon the lightsensitive cell S will vary in intensity in accordance with the synchronizing varia- A CORPORA- sensitive cell L will tions. The beam'of light is also subject to control by disc D in the following man ner: In case the motor M is rotating at such speed that the holes in disc D rotate past the'beam at a frequency equal to the frequency of the synchronizin variations, and the phase relation of the isc with respect to the synchronizing impulses is such that each pu se reaches a maximum as a. hole in disc D is centered with respect to the beam of light, the effect of the beam of light upon the light-sensitive cell LS will be a maximum. It will thus be seen that light-sensitive cell LS will beintermittently illuminated at a frequency equal,

to that of the synchronizing variations. The light-sensitive cell will cause amplifier A3 to produce corresponding current variations in the armature circuit of motor M. .In case disc D has such phase relation that a synchronizing pulse reaches its maximum when a solid portion of disc D is passing in front of the light ray, the efl'ect of the ray upon light-sensitive cell LS will be a minimum, and the current variations pro duced in the armature circuit of motor M will be ver small. For intermediate phase relations 0 the holes in disc D with respect to the synchronizing pulses, the effect of the light rays upon the light-sensitive cell will be to produce intermediate values of current variation in the armature circuit. The speed of motor M is adjusted by resistance R1 to such value that it is slightly below the desired synchronous speed. The effect of the current ulses produced by the light-sensitive cell L in the armature cir-' cuit is to increase the motor speed. Accordingly, disc D will assume such phase relation with respect to the synchronizing pulses or variations of lam L that the amplitude of the current pu ses produced by LSis just sufiicient to maintain the motor in synchronous operation with the incoming synchronizing pulses. In case the load upon the motor is increased for any reason, disc D will lag behind the synchronizing pulses by an amount suflicient to increase the amplitude of the current ulses produced by li lit-sensitive cell ES and to thereby supfpTy to the armature A, increased current su cient to accommodate the increased load. Conversel if'the load is decreased from its norma value, the motor will momentarily speed up and cause disc D to advance in phase relation with respect to the -synchronizin variations, and the resulting current u roduced by lightcorrespondingly reduced, and the motor will be prevented from getting out of s nchronism.

The arran ement s own in Figure 2 is the same as t at shown in Figure 1, except for the details of the motor control arrangement. In this figure, as, in Figure 1, both of short-circuit of resistance the armature and the field of the motor are supplied with currentfrom battery B. The armature circuit of the motor also includes an adjustable resistance B1. In a shunt path around resistance R1, a rotating com-' mutator CM mounted upon the shaft of the motor is connected in series with contacts GT--CP of a special electric relay. The relay comprises a lass tube MF provided with an electrode T) mounted in each end thereof. The tube is filled with an acidulated solution and also contains a globule of mercury GM immersed within the solution. The insulated contacts GT-CP are mounted upon the tube andextend into the solution and normally contact with the globule of mercury as shown in the figure. Electrodes E-E are connected to the output circuit of amplifier A1,; and contact points GTCP are connected in series with commutator CM in a shunt circuit around resistance R1 in the armature circuit.

The operation of Fi ure 2 is as follows: The s eed of motor is adjusted by resistance 1 until it is slightly lower than the desired synchronous speed. With contacts GTCP bridged by mercury GM, resistance R1 will be periodically short-circulted by commutator CM, twice for each revolution, and the time of short-circuit will depend upon the extent of the contact surface of the commutator and upon the speed of the motor.

When amplified low frequency current from amplifier A1 flows through the relay between electrodes EE, the globule of between contact points GTCP. The connection between contacts GT-CP will, therefore, be broken synchronously with the synchronizing impulses.

It will thus-be seen that the effectiveness of resistance R1 in the armature circuit is dependent upon the conjoint action of the commutator CM aiid the rela and the time 1 is de ndent upon the phase relationship existinfg etween the commutator and the relay. I the commutator and the relay operate simultaneously to close their. respective contacts, resistance R1 will be effectively cut out of the; armature circuit for a maximum period. If the commutator and relay become displaced/ in phase in their operation the period of short-circuit will be reduced and resist- -mercury elongates and breaks the connection creased for any reason, the commutator CM tends to lag behind the operation of the reto increase the armature current by an amount necessary to compensate for the increased load. Conversely, if the load. upon the motor is decreased, the commutator CM tends to "advance in. phase relation with respectto the operation of the relay and thereby decrease the period of short-circuit of resistance R1 which will offset the tendency of the motor to increase in speed above synchronous speed.

The arrangement shown in Figure 3 is the same as that shown in Figure 2, except for the details ofthe relay. The relay shown in Figure 8 comprises a contact arm CA pivoted at a point (a). Cooperating with the contact arm is a stationary contact plate current.

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CP. The arm CA is normally held out of contactwith plate OP by means of a wire W, one end of which is attached to the arm and the other end is anchored to a fixed' terminal (6). A spring S1 is attached to the arm CA and tends to cause the arm to contact with plate GP. Wire W is connected to the output circuit of amplifier A1,

and contact arm CA and plate OP are connected in series with commutator CM in a shunt path around resistance R1. Wire W is made of such material and such diameter that it is readily heatedby current supplied from amplifier A1. The efiect of the pulsating current flowing in wire W is to cause the wire to become elongated periodically and in synchronism with the synchronizing impulses. Spring S1 causes the arm CA to contact with plate GP each time wire W is elongated by the amplified current. Thus, the relay contacts will be closed periodically and in synchronism with the synchronizing signals. The action of the arrangement shown in Figure 3 will be readily understood from the foregoing explanation of the operation of Figure 2'.

It is apparent that the arrangements shown in Figures 2 and 3 will also operate with only the relay connected in the shunt path around resistance R1, and. the commutator CM connected in thegarmature circuit so as" to periodically interrupt the total armature -While I have shown symbolically, andfor the purpose of illustrationonly, a recording apparatus comprisin an inking pen operated by a magnet it will readily be understood that any other well known type of recording apparatus may be employed, such for example, as well known photographic recording apparatus.

The circuits of the relays have very little inductance and offer small impedance to high frequency currents.

It is to be noted that in Figure 1, I employ a form of electric relay having no moving mechanical parts, and the motor control system .does not employ vibrating or sliding electric contact devices.

What I claim is 1. In a synchronizing system the combination of means for producing synchronizing current variations, a motor to be synchronized, a source of current for operating said motor, means for translating said current into correspondin light ,,variations, means to translate said light variations into current variations in the motor circuit, and meanscontrolled by the motor to vary the eifect' 'of said light variations upon the current in the motor circuit.-

2. In a synchronizing system the combination offimeans for producing synchronizing current variations, a motor to be synchronized, a source of current for operating .said motor, means for translating said curnation of meansofor producing synchronizing current variations, a motor to be synchronized, a source of current for operating said motor, means for translating said our rent into corresponding light variations, means to translate said light variations into current variations in the motor circuit,

means for controlling the effect of said light variations in accordance with the relative phase displacement between the angular rotation of the motor and the synchronizing variations.

4. The method of synchronizing the operation of a motor which consists in continuously transmitting'from a sending station synchronizing current impulses, translating the said impulses into corresponding light variations, controlling the current supplled to the motor in accordance with the light variations, and varying the efiect of the light variations in accordance with the speed of the motor.

5." The method of synchronizing the operation of a motor which consists in continuously transmitting from a sending station synchronizing current impulses, translating the said impulses into corresponding light variations, controlling the current supplied to the motor in accordance with the light variations, .and varying the effect of the light variations in accordance with the relative phase displacement between the angular rotation of the motor and the synchronizin impulses.

6. V n a synchronizing system the combination of means for producing synchronizing current variations, a motor to be s chronized, a source of current for operati said motor, an incandescent lamp controll eig by the synchronizing current, a light-sensitive cell controlled by light from said lamp and connected to supply current variations to saidmotor circuit, and a light-interrupting disc driven by the motor and arranged between the lamp and light cell.

7. An electric relay system comprising means for translating current variations into correspondin light variations, means for translating sai light variations into current variations, and means controlled by said current variations for controlling the action of the light upon the light translating means.

n a synchronizing system the combination of means for producing synchronizing current variations, .a motor to be synchronized, a periodic circuit interrupter operated b said motor, a second circuit interrupter liaving an operating circuit of substantially no inductance connected to the source of synchronizing current, and circuit connections whereby the operation of the motor is controlled bythe conjoint action of said interrupters.

. In testimony whereof I have afiixed my signature.

CHARLES FRANCIS JENKINS.

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