US2453203A - Variable frequency relaxation oscillator - Google Patents

Variable frequency relaxation oscillator Download PDF

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Publication number
US2453203A
US2453203A US491439A US49143943A US2453203A US 2453203 A US2453203 A US 2453203A US 491439 A US491439 A US 491439A US 49143943 A US49143943 A US 49143943A US 2453203 A US2453203 A US 2453203A
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Prior art keywords
frequency
oscillator
point
potential
tube
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US491439A
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Arthur H Dickinson
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International Business Machines Corp
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International Business Machines Corp
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Priority to DEI2060A priority patent/DE976160C/de
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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F7/00Methods or arrangements for processing data by operating upon the order or content of the data handled
    • G06F7/38Methods or arrangements for performing computations using exclusively denominational number representation, e.g. using binary, ternary, decimal representation
    • G06F7/48Methods or arrangements for performing computations using exclusively denominational number representation, e.g. using binary, ternary, decimal representation using non-contact-making devices, e.g. tube, solid state device; using unspecified devices
    • G06F7/491Computations with decimal numbers radix 12 or 20.
    • G06F7/4912Adding; Subtracting
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03KPULSE TECHNIQUE
    • H03K4/00Generating pulses having essentially a finite slope or stepped portions
    • H03K4/06Generating pulses having essentially a finite slope or stepped portions having triangular shape
    • H03K4/08Generating pulses having essentially a finite slope or stepped portions having triangular shape having sawtooth shape
    • H03K4/86Generating pulses having essentially a finite slope or stepped portions having triangular shape having sawtooth shape using as active elements gas-filled tubes or spark-gaps
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03KPULSE TECHNIQUE
    • H03K6/00Manipulating pulses having a finite slope and not covered by one of the other main groups of this subclass
    • H03K6/04Modifying slopes of pulses, e.g. S-correction
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F2207/00Indexing scheme relating to methods or arrangements for processing data by operating upon the order or content of the data handled
    • G06F2207/491Indexing scheme relating to groups G06F7/491 - G06F7/4917
    • G06F2207/49195Using pure decimal representation, e.g. 10-valued voltage signal, 1-out-of-10 code

Definitions

  • the general object of the invention resides in the provision of a novel method and means of automatically changing the frequency and/or phase of an electrical oscillator.
  • An object of the invention is, further, to provide novel means for abruptly changing the frequency of an electrical oscillator and abruptly restoring the oscillator to its original frequency.
  • An object of the invention is, still further, to provide means for changing the phase of the oscillations produced by an electrical oscillator by temporarily changing the frequency of the oscillations.
  • Another object of the invention is to provide a novel electronic circuit for automatically determining the value or values of elements of an oscillator circuit so as to govern the frequency of oscillations produced by the oscillator circuit.
  • Another object of the invention is to provide a novel method and means for changing a, given frequency of an electrical oscillator to a submultiple of the given frequency.
  • Fig. 1 is a circuit diagram of the main form of the invention, showing an arrangement for multiplying a chosen oscillator frequency.
  • Fig. 2 is a circuit diagram of a modication, showing an arrangement for changing the chosen frequency to a submultiple thereof.
  • Fig. 3 is a ldiagrammatic showing of Waves produced by the circuit of Fig.A 1 when the chosen frequency is doubled for a temporary interval having a predetermined relation to the chosen cycle.
  • Fig. 4 shows the timing, in relation to the chosen cycles, of the electrical control effects pertinent to the Waves shown in Fig. 3.
  • Fig. 5 is a diagrammatic showing of wave forms produced by the circuit of Fig. 1 when the chosen frequency is tripled for predetermined intervals.
  • Fig. 6 is a. timing diagram of the electrical effects pertaining to the Waves shown in Fig. 5.
  • Fig. 7 is a diagrammatic showing of waves produced by the circuit of Fig. 2 when the chosen frequency is temporarily halved
  • Fig. 8 is a timing diagram of the electrical effects pertaining to the waves shown in Fig. 7.
  • Theinvention is disclosed in connection with an oscillator of the type known as ⁇ a relaxation oscillator.
  • the circuit value of an element or elements of the oscillator is varied to produce achange in frequency.
  • the means for varying the circuit value comprises a control network including a gas-filled tube and vacuum tubes.
  • the voltage distribution about the network differs according to whether the gasiilled tube is or is not conducting current.
  • the value of an element or elements of the oscillator will be determined by the voltage distribution of the network which distribution is determined, in turn, by the status of the gas-filled tube. A change in the status of the gas-lled tube will automatically produce a change in frequency of the oscillator.
  • the status of the gas-filled tube is controlled by the changes in impedance of the vacuum tubes of the control network. Voltage applied to a firing control portion of the network, such portion including a vacuum tube, will cause ignition of the gas-filled tube, while voltage applied to a shut-off control portion of the network, such portion also including a vacuum tube, will cause the gas-filled tube to be extinguished.
  • a relaxation oscillator is that type in which a condenser is charged, through an impedance, and discharged periodically, the discharge occurring upon short circuiting of the condenser. During the charging vportion of a cycle, there is a constant increase in voltage difference between the condenser terminals. The short circuiting o-f the condenser causes its substantially instantaneous discharge. Thus, such oscillator produces a sawtoothed wave.
  • a gas triode is used as the short circuiting device and a multigrid tube; specifically, a pentode, is used as the impedance in the condenser charging circuit.
  • the pentode is used because its characteristics are such that for widely varying anode potentials, the current ilo-w therethrough remains substantially constant for a given grid bias setting. Therefore, at whatever frequency the oscillator is operating, the rise in voltage across the con- -denser will be substantially linear.
  • the gas triode is used as a short circuiting device because its grid bias may be conveniently regulated to determine at what voltage across the condenser the triode is to break down and short circuit the condenser.
  • the frequency ofthe oscillator will be automatically changed upon a change of voltage distribution about thecon-trol network external to the oscillator. Such change will be eiected at a chosen point of a cycle.
  • a given frequency of the oscillator is chosen conveniently as determining the base cycle. This given or chosen frequency also may be referred to as the base frequency.
  • the frequency will be changed at a denite point of the base cyclev and at least some of the waves produced at the changed. frequency will have a different phase with respect to the base cycle than the oscillations produced at the base frequency.
  • the return of the oscillator to the base frequency will be effected also at a denite point of a base cycle.
  • the oscillations thereafter produced at the base frequency Will have either the same or a different phase than the base frequency oscillations which were being generated prior to the intervening change in frequency.
  • the new phase of the-basev frequency oscillations will depend on the base cycle time elapsing between shift of the oscillator to the changedfrequency and its return to the base frequency.
  • means are provided to automatically cause the oscillator to change from the base frequency to a multiple ,A
  • Fig. 1 is substantially similar, except for certain additions which will be described, to one of the circuits shown in my aforementioned copending application. For convenience, parts of Fig. 1 will be given the same reference characters as corresponding parts of the copending application.
  • plus and minus lines I and 2 receive D. C. voltage from a suitable source.
  • the relaxation oscillator comprises condenser 22, gas triode 26, and pentode 23.
  • ⁇ A resistor 2l connects the anode of the gas tube to line I while its cathode is connected to the anode of the pentode 23.
  • the cathode of the pentode is connected Via variable resistances 2.4 and to line 21.
  • IThus, gas triode 26 and pentode 23' are in series across the lines I and 2.
  • Condenser 22 is connected at one side to line l and at the opposite side to a point 6 intermediate the connection between the cathodev and anode of the gas tube and the pentode.
  • the condenser 22 is in parallel with the gas tube 28 and resistor 2? and is also in series with the pentode 23.
  • the control grid of gas tube 26 is connected via protective resistance SI to a point 33, of a voltage divider comprised of resistors ⁇ 34 and 35.
  • the voltage supplied the control grid to the gas tube is accordingly determined by the potential at point 33.
  • Pentode 23 has its screen grid connected via a switch 58
  • the potential of the screen grid is thus determined by the potential at the point of this voltage divider tapped by the connection to the screen grid, provided the switch 50i is in the position shown.
  • the screen grid is connected to a point of resistor 30 but it may be adjusted to point 28 or any other suitable point of the voltage divider 29-30.
  • the control grid of the pentode may be connected, as shown, to a selected .point of resistor 30.
  • the resistors 24 and 25 constitute a self-biasing resistance for the pentode.
  • One of these resistors is preferably adapted to afford a coarse adjustment of the self-bias and the other a ne adjustmentf Voltage divider 29--30 is part of the control network which experiences a change involtage distribution to automatically cause the oscillator frequency to depart from the base frequency.
  • the control network will a-ct through both the screen and control grids of the pentode to change the frequency of the oscillator.
  • the control grid mal7 be connected Vdirectly to line 2, so that its potential Will beviixed. The control network then will control the frequency through the screen grid alone.
  • control network change the frequency byV automatically varying the potential only of the control grid of the pentode, while the screen grid potentialremained Xed.
  • may bey thrown to a position opposite the shown position, connecting the screen grid to point 33 of Voltage divider 34-35.
  • the potential at point 33w-ill then determine not only the potentialofthe control grid of gas triode 26 but also the potential of the screen grid of pentode 23.
  • the control network includes, besides the mentioned voltage divider 29-30, two additional voltage dividers and a gas-filled triode 55.
  • One of these additional voltage dividers comprises resistor 38 and vacuum tube 39a.
  • This voltage divider serves as an extinguishing control for gas triode 55', in a manner which will be explained.
  • the other of the voltage dividers comprisesY a resistor 40, vacuum tube 42a, and resistor 4 I.
  • the latter voltage divider serves, in a manner to be explained, as a ring control for gas triode 55.
  • the gas triode 55 has its anode connected, via current limiting resistance 43, to a point 45 of voltage divider 38-3 9a and its cathode connected to point 28 of voltage divider 29-30.
  • the grid of triode 55 is connected via a 4protective resistance 3'I to a point 48 of the voltage divider 40-42a-4 I.
  • the resistor 4I is aself-biasing resistance for tube, 42a and normally keeps the tube at relatively high impedance. Point 48 is then nearer than point 28' to the potential of line 2. Under this conditiornthe. grid bias of the gas triode 55 is so high as to prevent its ignition even though ionization. potential is being'applied to the gas triode.
  • the voltage distribution about the control network is determined by the status of the gas tube 55. With the gas tube in conductive status, current flows from point 45 to point 28. The value of this current flow depends upon the relative values of the impedances of the voltage dividers between which the gas tube is interposed and also upon the setting of variable resistor 43. With the gas tube serving as a conductive bridge between points 45 and 28, there is increased current ow in resistor 38, resistance 43, and resistor 3U. Such increased current in these resistors causes the potential at point 45 to drop, and the potential at point 28 and at points along resistor 30 to rise.
  • the constants of the circuit are such that the difference in potential between points 45 and 28 will still be great enough to supply the necessary ionization potential for the tube 55.
  • the tube 55 when in a conductive state maintains points along voltage divider 29-30 at relatively high potential. Vhen the tube 55 is extinguished, the original voltage distribution about the control network is restored; that is, point 45 rises in potential, and points along voltage divider 29-30 drop to relatively low potential.
  • control grid will be connected to a point of resistor which eX- periences a greater rise in potential than the rise in potential of the cathode of the pentode. Hence, the net effect will vbe a reduced control grid bias for the pentode.
  • the ignition of tube 55 raises the potential at points of resistor 3U which, in turn, causes the screen and control grids of the pentode 23 to rise in potential, causing a reduction in impedance of the pentode.
  • the tube 55 is extinguished, reversal of the stated effects occurs and the impedance of the pentode returns to its original value.
  • a drop in impedance of the pentode 23 lincreases the frequency of the oscillator, and a rise in impedance of the pentode reduces the frequency.
  • the potential of points along the voltage divider 29-36 rises, causing the impedance of the pentode to fall, as a result of which the oscillator frequency is increased.
  • the reverse operations take place and the oscillator again functions at the base frequency.
  • the base frequency of the oscillator may be variably chosen by changing the setting of any one or more of the following: condenser 22, resistor 24, resistor 25, the tap point of the control grid to resistor 3U, and the tap point of the screen grid to resistor'B. It may be mentioned that further selection may be made by changing resistances 29 and 30'.
  • switch 50i When switch 50i is in position opposite the one shown, the screen grid is connected to point 33 and will be excluded from consideration in regard to variable selection of the base frequency. Likewise, if the control grid be connected to line 2, it will be excluded as a factor of adjustment of the base frequency.
  • Fig. 3 is a diagrammatic showing of waves produced on the assumption that the circuits are adjusted to double the base frequency upon ignition of gas tube 55.
  • the base cycle as previously stated, is taken as the cycle of an oscillation generated at base frequency.
  • This base cycle referred to hereafter simply as the cycle, is divided, for convenience, into ten parts and the dividing points arenumbered l0, 9 l.
  • Thevvaves may be taken to represent the changing voltage at a point, such as 6, of the oscillator.
  • phase of thefoscillations produced at base frequency may be shifted in accordance with the point of the cycle at which 'the doubling of the requency occurred and thefpoint of the cycle at which the return to base frequency was effected. With the operations timed as in Fig. 3, the phase of base frequency oscillations has been shifted from 2 to 8.
  • Fig. 5 illustrates waves produced on the assumption that the circuits are adjusted to triple the base frequency upon ignition of the gas triode 5'5.
  • Fig. 6 is companion to Fig. 5.
  • the oscillations Prior to ignition of the rgas triode, the oscillations are assumed to have a 4 phase.
  • the gas tube 55 is ignited, fOr example, at point-9 of cycle c.
  • the rise in potential of point 28 is indicated at 501 of Fig. 6 and the accompanying change of frequency is indicatedv at 508 of Fig. 5.
  • the waves now being produced at triple the base 'frequency have successive phases of 7l/3, 4, and 102/3. It is assumed that the oscillator is to return to base frequency at of cycle d; i. e., at the beginning of this cycle.
  • the circuits may be adjusted for other multiples of the base frequency; that is, the base frequency may be quadrupled or increased ve times, and
  • Fig. 2 shows a circuit arrangement whereby the ignition of the gas tube in the control network causes a reduction of vthe base frequency
  • the control network comprises three impedance branches :or voltage dividers across the plus and minus lines IA and 2A.
  • Application of a pulse to resistance 41A increases current flow in voltage divider 40A- 42A-MA.
  • Gas tube 55A thereupon fires.
  • a vpulse is applied to resistory v8
  • the oscillator per se of Fig. 2 is similar to the one of Fig. l andcomprises condenser 22A, gaseous discharge tube 25A, and. pentode 23A'.
  • the screen grid lof the pentode is shown as connected directly to point 33A of voltage divider 35A-35A.
  • the screen vol-tage is thus fixed, andthe impedance -of the pen-tode will vary with the control ⁇ grid bias.
  • the control grid ofthe pentode 23A is connected to a chosen point 5
  • sistors 24A 4and 25A are of the same nature asresistors 24 and 25 of Fig. l.
  • Resistor 25A is connected by la wire 52
  • the difference in potential between point 36A and point 5H) ⁇ is the net icontrol grid bias for the pentode 23A.
  • rises and increases the net self-bias of pentode 23A. Impedance of the pent-ode is increased as a result, andthe frequency of the wosf cillator reduced.
  • the ratio of the new frequency to the base frequency depends upon the constants of ythe impedance network and upon the setting of point 52
  • the base frequency may beselected by adjusting the setting of one or more of the following: points 5
  • the circuits of Fig. 2 cause the frequency-to be decreased upon firing of the gas tube 55A, the reverse of the effect produced by :the firing of ⁇ the gas tube 55 of Fig. 1.
  • the extinction -of the gas ⁇ tube 55A restores the oscillator to the base frequency.
  • Fig. 7 shows a change in the oscillations produced upon the assumption that the circuits of Fig. 2 have been adjusted to cause the base frequency to be halved upon ignition -of -thegas tube y 55A.
  • the base oscillations are shown as initially having an 8 phase.
  • ⁇ the gas tube 55A is red at point 4 of cycle c.
  • (Fig. 2) is indicated at. 522 of Fig. 8, and the :accompanying change in frequency is indicated at 523 -of Fig. '7.
  • the oscillator now functions at half :the baserate.
  • circuits of Fig. 2 may be adjusted for causing the base frequency to be reducedV to other fractions than one half, upon ignition of .the gas tube 55A.
  • the oscillator may bev maintained at a changed frequency, either a multiple or a fraction of the base frequency, for
  • an electrical oscillator circuit including an automatically variable impedance element adjustable in impedance value to determine one -or another frequency of the oscillator circuit, and a control circuit including signal responsive means responsive to an electrical signal for automatically adjusting the impedance value of said variable impedance element so as to produce a change in frequency of the oscillator circuit, said contr-ol circuit further including electronic discharge means for sustaining the impedance constantly at the adjusted value after the signal has disappeared, and said control circuit being responsive to a later signal to restore the operation of the oscillator circuit, and a .control Y, network including means responsive to one elec- -trical signal for :automatically adjusting the impedance value of said variable impedance means to cause la change in operation of the oscillator circuit and including mean-s responsive to av following, like -electrical signal for automatically restoring the variable impedance means to its Previous impedance value so as to cause the oscillator cir-cuit to rever-t to its previous operation to operate in a phase differ
  • an electrical oscillator circuit adjusted to produce waves at ⁇ a base frequency in any of different pos-sible phases within a chosen time base
  • a control network automatically adjusting the constants of the oscillator circuit and having self-sustained alternative conditions in one of which it maintains the circuit so adjusted as .to operate at the base frequency .and in another of which it so alters the constants of the circuit as to cause it to depart from the base frequency
  • signal responsive means operating in response to one electrical signal to alter the network from one of its conditions to the lother and operating in response to a later electrical signal to restore the network to its previous condition, so as to produce a temporary departure of the oscillator circuit from base frequency in order to effect an automatic phase shift thereof.
  • a gas-tube type of relaxation oscillator circuit adjusted to produce waves at a base frequency in any of different possible phases within a chosen .time base
  • a control network automatically controlling the constants of the oscillator circuit and having alternative sustained, relatively reverse conditions in one of which it maintains the -oscillator circuit so 'adjusted as to produce the waves at the base frequency :and in the other condition of which it so zalters the constants of the oscillator circuit as to depart from the base frequency
  • electrical signal pulse-operated means for adjusting the network first to one said condition in response to one pulse and then to the alternative, reverse condition in response to a following pulse, whereby the network is enabled to automatically cause the oscillator circuit to depart from the base frequency and return thereto upon successive reverse changes in condition of the network in response to successive electrical signal pulses, so that upon return to its. base frequency the oscillator is in a phase differing from its previous phase according to the interval between the signals.
  • an electrical relaxation oscillator circuit adjusted to operate at ⁇ a given frequency in any of different possible phases with respect .to a given time base, a control network comprising a gas tube with a control grid, a firing control in the network responsive to an applied electrical signal for firing the gas tube to obtain one electrical condition Iof the network, an extinguishing control in the network responsive to a subsequent, applied electrical signal for extinguishing Ithe gas tube to obtain an alternative electrical condition of the network, and means electrically coupling the network to the -oscillator circuit so as automatically to adjust it differently in accordance with the different conditions of the network thereby to produce a phase shift in the oscillator circuit determined in extent by the interval relative to the time base, between the firing and extinguishing signals.
  • an electrical oscillator circuit including an electrical element variable in electrical value and normally at such value ⁇ as to cause the oscillator to operate at a given frequency in any of different possible phases with respect to a chosen time base 4said element being adjustable in value to vcause the oscillator yto change its frequency and produce a phase shift, a trigger circuit having alternative sustained electrical conditions and electrically connected to said element of the oscillator circuit for varying its electrical value in accordance with said electrical conditions,and signal responsive means responsive to one electrical signal for producing one of said sustained electrical conditions of the trigger circuit and responsive to a following electrical signal for returning the trigger circuit to its alternative sustained condition, whereby the sustained electrical conditions of the trigger circuit are alternated in response to successive electrical signals so as to automatically act upon .the oscillator circuit to shift its phase,
  • an oscillator circuit of the relaxation type adjusted to produce waves at -a given frequency yand phased selectively with respect to a chosen time base, a control circuit changeable in electrical condition in response to one electrical signal pulse and returnable to previous electrical condition in response to a subsequent electrical signal pulse, and means so operatively connecting the control circuit to the oscillator circuit as Ito automatically transmit the effect of ⁇ the change and return in condition of the control circuit to the oscillator circuit, thereby to cause a temporary readjustment of the oscillator circuit and correspondingly temporary change in its frequency, so as to shift the oscillator circuit phase in accordance with the time, relative -to the time base, elapsing between the successive electrical signal pulses.
  • an electrical oscillator circuit adjusted to operate at a given frequency in any of different possible phases with respect to a chosen time base and including a variable impedance electronic discharge device determining the frequency of :the oscillator circuit, a trigger circuit having alternative sustained electrical conditions and triggered in response to one electrical 11 signal to one sustained condition and in response to a subsequent electrical signal triggered back -to a previous sustained electrical condition, and means electrically operatively connecting .
  • an electrical oscillator 'ci1'- cuit adjusted 'to operate at a given 'frequency in any Iof different possible phases with respect to a chosen time base
  • a control circuit including a trigger tube for determining the electrical condition of the circuit, means so electrically coupling the con-trol circuit to the -oscillator circuit so as to adjust the latter in vaccordance with the electrical condition of the former, ⁇ and means in ythe control circuit responsive to one electrical signal'f-or triggering the tube in one direction and responsive vto a subsequent signal for triggering the tube in the reverse direction thereby to cause successive reverse changes in electrical lcondition of the control circuit, such changes being effective Ito produce corresponding lsuccessive reverse adjustments of the osillator circuit, whereby ythe phase of the oscillator circuit is shifted in accordance with the time, relative to said time base, el-apsing between the successive ltriggering operations of the trigger tube.
  • An oscillator comprising a gaseous discharge device having an anode, a cathode and ya grid, a source of anode to cathode power, ⁇ 2
  • Aan electron emission device including at least an anode,-a cathode andone grid, means conductively connectin'gsaid device in series with said ygaseous disch-arge 'device andsaid power source, and a potentiometer, in shunt with said gaseous discharge device and said electron emission device in series, a second 'gaseous discharge device connected' in shunt witna portion of said'potentiometerand means for igniting and quenching said second discharge device yto thereby produce a variation'inthe voltage at a predetermined point of said potentiometer, andmeans connecting said predeterminedpoint Iand said one grid of theelectron 'emission :device

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Theoretical Computer Science (AREA)
  • Computational Mathematics (AREA)
  • Mathematical Analysis (AREA)
  • Mathematical Optimization (AREA)
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  • Stabilization Of Oscillater, Synchronisation, Frequency Synthesizers (AREA)
US491439A 1943-06-19 1943-06-19 Variable frequency relaxation oscillator Expired - Lifetime US2453203A (en)

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Application Number Priority Date Filing Date Title
US491439A US2453203A (en) 1943-06-19 1943-06-19 Variable frequency relaxation oscillator
DEI2060A DE976160C (de) 1943-06-19 1950-09-22 Saegezahngenerator mit veraenderbarer Phasenlage fuer Zaehl- und Rechenwerke

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Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2075140A (en) * 1931-05-21 1937-03-30 Schlesinger Kurt Tilting oscillator and modulator
US2132654A (en) * 1934-10-18 1938-10-11 Rca Corp Electrical apparatus
US2227815A (en) * 1936-07-08 1941-01-07 Toulon Pierre Marie Gabriel Synchronization system for television
US2241256A (en) * 1937-12-31 1941-05-06 Bell Telephone Labor Inc Circuit for cathode ray tubes
US2266516A (en) * 1938-03-30 1941-12-16 Rca Corp Saw-tooth wave generator
US2275460A (en) * 1939-11-01 1942-03-10 Robert M Page Electron beam control apparatus
US2301195A (en) * 1941-08-30 1942-11-10 Remington Arms Co Inc Measuring instrument
US2350797A (en) * 1940-06-21 1944-06-06 Morland Preben Means for producing electric impulses
US2424617A (en) * 1944-03-13 1947-07-29 Robert L Hoyle Power steering mechanism for tractors
US2428926A (en) * 1943-06-04 1947-10-14 Rca Corp Modified sweep circuit for cathoderay tubes

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1867171A (en) * 1929-02-26 1932-07-12 Rca Corp Tone stabilizing
CH201785A (de) * 1938-02-17 1938-12-15 Gustav Dipl Ing Guanella Verfahren und Einrichtung zur Gleichlaufregelung des Ablenkspannungserzeugers bei Bild- oder Fernsehübertragungseinrichtungen durch Synchronisierungszeichen.

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2075140A (en) * 1931-05-21 1937-03-30 Schlesinger Kurt Tilting oscillator and modulator
US2132654A (en) * 1934-10-18 1938-10-11 Rca Corp Electrical apparatus
US2227815A (en) * 1936-07-08 1941-01-07 Toulon Pierre Marie Gabriel Synchronization system for television
US2241256A (en) * 1937-12-31 1941-05-06 Bell Telephone Labor Inc Circuit for cathode ray tubes
US2266516A (en) * 1938-03-30 1941-12-16 Rca Corp Saw-tooth wave generator
US2275460A (en) * 1939-11-01 1942-03-10 Robert M Page Electron beam control apparatus
US2350797A (en) * 1940-06-21 1944-06-06 Morland Preben Means for producing electric impulses
US2301195A (en) * 1941-08-30 1942-11-10 Remington Arms Co Inc Measuring instrument
US2428926A (en) * 1943-06-04 1947-10-14 Rca Corp Modified sweep circuit for cathoderay tubes
US2424617A (en) * 1944-03-13 1947-07-29 Robert L Hoyle Power steering mechanism for tractors

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