US1947182A - Constant frequency apparatus - Google Patents

Constant frequency apparatus Download PDF

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US1947182A
US1947182A US459772A US45977230A US1947182A US 1947182 A US1947182 A US 1947182A US 459772 A US459772 A US 459772A US 45977230 A US45977230 A US 45977230A US 1947182 A US1947182 A US 1947182A
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frequency
oscillator
wave
crystal
electric
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US459772A
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Philander H Betts
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01RMEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
    • G01R23/00Arrangements for measuring frequencies; Arrangements for analysing frequency spectra

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  • This invention relates to constant frequency apparatus, and particularly to apparatus which may be assembled into a compact and portable unit, and may be utilized to measure the free quency of an unknown wave, or produce a wave of known frequency, with great accuracy.
  • a feature of this invention is a piezo-electric crystal controlled oscillation generator, and means for comparing the frequency of an electric oscillation generator with waves produced thereby.
  • two oscillation generators are provided, one of which may be controlled by electrical reactances, and be capable of generating waves over a wide range of frequencies, and the other of which is mechanically controlled, as by a piezo-electric crystal (which may be of quartz, for example), so as to be capable of generating a wave whose frequency is constant within very narrow limits.
  • a piezo-electric crystal which may be of quartz, for example
  • a wave of unknown frequency whose frequency is to be determined, is intermodulated with a wave from the electric oscillation generator, and a zero beat note obtained.
  • the setting of the electrical reactances for this zero beat is noted.
  • the wave of unknown frequency is then replaced by the output of the crystal controlled oscillator, and a zero beat is then obtained between the two nearest settings of the reactances which will give a zero beat with two characteristic frequencies of the crystal controlled oscillator which may comprise the fundamental and a harmonic of the wave from said oscillator or two harmonics thereof.
  • Fig. l is a diagram showing one form of circuit for utilizing the principles of this invention.
  • Fig. 2 is a schematic diagram illustrating how the various portions of the circuit function.
  • an oscillation generator marked Electric oscillator comprises a three-electrode space discharge device 24, a filament battery 3, grid biasing resistance 8, and plate battery 4 which is shunted by by-pass condenser 5. Its frequency is controlled by a tuned circuit consisting of a variable condenser 1 and variable inductances 2,
  • a wave the frequency of which is to be determined, may be impressed on the detector from another source by means of the coupling between an inductance 6 and inductance '7.
  • a piezo-electric crystal controlled oscillation generator marked Crystal oscillator comprises a three-electrode space discharge device 25, the plate of which is connected to one side of a tuned circuit consisting of an inductance 10 and variable condenser 17. From a point on the inductance a tap leads through a plate battery 11,V shunted by a by-pass condenser 12, to the filament. The other side of the tuned circuit is connected through arpiezo-electric crystal, 13, to the grid. The filament is heated by batteryY 9. The grid electrode of the crystal oscillator is biased through resistance 14 connected between its grid and filament.
  • the tuned circuit 10-17 may be adjusted to give a large inductive reactance in the plate circuit of the crystal oscillator, and provide some feed-back into the grid circuit to assist in production of crystal oscillation.
  • a harmonic producer and detector comprises a threeelectrode space discharge device 26 having the inductance 7 and resistance 14 in its input circuit. Its filament is heated by a battery 18. Its plate is connected to its filament through a high frequency by-pass condenser 16. In parallel to the condenser 16 there is provided in series a high frequency choke coil 19 and two parallel circuits which include respectively a resistance 20 for regulating the plate voltage, a low frequency choke coil 21, and plate battery 22, and an audio frequency condenser 23 and telephone receiver 15.
  • the telephone receiver 15 may be replaced by a 95 meter or other suitable device for indicating the frequency of a beat note produced in the output circuit of the detector.
  • the circuit shown is, of course, simply illustrative of one manner of utilizing the principles v100 of the invention, and may be modified in any desired manner Without departing from the scope of the invention.
  • the harmonics of the crystal frequency may be produced in the crystal oscillator and the harmonic producer and detector 105 used for detection only, or the harmonics may be produced and the detection performed each in separate devices.
  • crystal oscillator is controlled by a crystal whose fundamental frequency of vibration is exactly 100 kilocycles and that an unknown frequency is to be measured whose frequency is, say, 2,835,000
  • the unknown frequency is impressed on the detector through the amplifier together with a wave from the electric oscillator.
  • the electric oscillator is then adjusted to give a zero beat note in the beat frequency indicator, and the condenser setting of the electric oscillator noted.
  • the crystal oscillator is turned off
  • the unknown frequency is now turned ofi and the crystal oscillator is turned on.
  • the electric oscillator is now adjusted to give a zero beat with the nearest harmonic from the crystalV oscillator. This will be the 28th harmonic which will give a condenser setting of the electric oscillator for 2,800,000 cycles.
  • Another adjustment is then made for zero beat with the nearest harmonic in the other direction. This will give another setting corresponding to 2,900,000 cycles.
  • the process is very similar. If it is desired to produce an output of 2,835,000 cycles, say, the settings of the vacuum tube oscillator for 2,800,000 cycles and 2,900,000 cycles are found by comparison with the corresponding harmonics of the crystal oscillator, and the setting for the desired frequency found by interpolation.
  • the known frequency output is taken olf through inductance 6 (Fig. 1). If straight line frequency control is used, the interpolation may be made with greater accuracy and facility.
  • a crystal calibrated wave meter comprising an electric oscillator, a crystal oscillator, a detector, and means for receiving a wave of unknown frequency, in combination with means for impressing waves from said electric oscillator and said crystal oscillator on said detector, means for impressing the wave from said electric oscillator and said unknown wave on said detector, and means for observing a beat note produced in said detector.
  • the method of measuring the frequency of anV unknown wave in a calibrating instrument comprising means for receiving said unknown wave, a variable frequency electric oscillator, a crystal oscillator, a detector and a signal indicator, which comprises impressing said unknown wave anda wave from said electric oscillator on said detector and adjusting the frequency of the wave from the electric oscillator for a zero beat in said signal indicator, impressing waves from said electric oscillator and said crystal oscillator on said detector and again adjusting the frequency or the wave from the electric oscillator for a zero beat in the signal indicator for the two harmonics of the crystal oscillator nearest to the frequency of the unknown wave, and interpolating between said last adjusted frequencies to determine the frequency of the unknown wave corresponding to the rst adjusted frequency.
  • a signal indicator which comprises I impressing waves from said electric oscillator and said crystal oscillator on said detector and adjusting the frequency of the wave from the electric oscillator for a zero beat in said signal indicator between the two nearest harmonics of the crystal PHILANDER H. BETTS

Description

N Febb 13, 1934. P. H, Bl-:Trs
CONSTANT FREQUENCY APPARTUS Filed June 7, 1930 A TTOP/VE Y Patented Feb. 13, 1934 UNITED STATES CONSTANT FREQUENCY APPARATUS Philander H. Betts, Behnar, N. J., assignor to Bell Telephone Laboratories, Incorporated, New York, N. Y., a corporation of New York Application June 7, 1930. Serial No. 459,772
3 Claims. (Cl. Z50-36) This invention relates to constant frequency apparatus, and particularly to apparatus which may be assembled into a compact and portable unit, and may be utilized to measure the free quency of an unknown wave, or produce a wave of known frequency, with great accuracy.
A feature of this invention is a piezo-electric crystal controlled oscillation generator, and means for comparing the frequency of an electric oscillation generator with waves produced thereby.
In utilizing the principles of this invention two oscillation generators are provided, one of which may be controlled by electrical reactances, and be capable of generating waves over a wide range of frequencies, and the other of which is mechanically controlled, as by a piezo-electric crystal (which may be of quartz, for example), so as to be capable of generating a wave whose frequency is constant within very narrow limits. There is also provided means for producing harmonies of the waves so generated, and for intermodulating and comparing the waves so produced.
In the operation of one form of the device of the invention a wave of unknown frequency, whose frequency is to be determined, is intermodulated with a wave from the electric oscillation generator, and a zero beat note obtained. The setting of the electrical reactances for this zero beat is noted. The wave of unknown frequency is then replaced by the output of the crystal controlled oscillator, and a zero beat is then obtained between the two nearest settings of the reactances which will give a zero beat with two characteristic frequencies of the crystal controlled oscillator which may comprise the fundamental and a harmonic of the wave from said oscillator or two harmonics thereof. This gives two points of known frequency for the electric oscillator, and by interpolation the frequency of the unknown wave may be determined with great accuracy.
In the drawing, Fig. l is a diagram showing one form of circuit for utilizing the principles of this invention; and
Fig. 2 is a schematic diagram illustrating how the various portions of the circuit function.
In Fig. l an oscillation generator marked Electric oscillator comprises a three-electrode space discharge device 24, a filament battery 3, grid biasing resistance 8, and plate battery 4 which is shunted by by-pass condenser 5. Its frequency is controlled by a tuned circuit consisting of a variable condenser 1 and variable inductances 2,
and it may be calibrated in harmonics of the frequency of a piezo-electric crystal to be described. The oscillations generated are impressed on a harmonic producer anddetector by means of coupling between inductances 2 and induc- V60 tance 7. A wave, the frequency of which is to be determined, may be impressed on the detector from another source by means of the coupling between an inductance 6 and inductance '7.
A piezo-electric crystal controlled oscillation generator marked Crystal oscillator comprises a three-electrode space discharge device 25, the plate of which is connected to one side of a tuned circuit consisting of an inductance 10 and variable condenser 17. From a point on the inductance a tap leads through a plate battery 11,V shunted by a by-pass condenser 12, to the filament. The other side of the tuned circuit is connected through arpiezo-electric crystal, 13, to the grid. The filament is heated by batteryY 9. The grid electrode of the crystal oscillator is biased through resistance 14 connected between its grid and filament. The tuned circuit 10-17 may be adjusted to give a large inductive reactance in the plate circuit of the crystal oscillator, and provide some feed-back into the grid circuit to assist in production of crystal oscillation.
A harmonic producer and detector comprises a threeelectrode space discharge device 26 having the inductance 7 and resistance 14 in its input circuit. Its filament is heated by a battery 18. Its plate is connected to its filament through a high frequency by-pass condenser 16. In parallel to the condenser 16 there is provided in series a high frequency choke coil 19 and two parallel circuits which include respectively a resistance 20 for regulating the plate voltage, a low frequency choke coil 21, and plate battery 22, and an audio frequency condenser 23 and telephone receiver 15. The telephone receiver 15 may be replaced by a 95 meter or other suitable device for indicating the frequency of a beat note produced in the output circuit of the detector.
The circuit shown is, of course, simply illustrative of one manner of utilizing the principles v100 of the invention, and may be modified in any desired manner Without departing from the scope of the invention. The harmonics of the crystal frequency may be produced in the crystal oscillator and the harmonic producer and detector 105 used for detection only, or the harmonics may be produced and the detection performed each in separate devices.
The operation of the invention may be best described by reference to Fig. 2. Assume that the .H0
cycles.
crystal oscillator is controlled by a crystal whose fundamental frequency of vibration is exactly 100 kilocycles and that an unknown frequency is to be measured whose frequency is, say, 2,835,000 The unknown frequency is impressed on the detector through the amplifier together with a wave from the electric oscillator. The electric oscillator is then adjusted to give a zero beat note in the beat frequency indicator, and the condenser setting of the electric oscillator noted. During this operation the crystal oscillator is turned off The unknown frequency is now turned ofi and the crystal oscillator is turned on. The electric oscillator is now adjusted to give a zero beat with the nearest harmonic from the crystalV oscillator. This will be the 28th harmonic which will give a condenser setting of the electric oscillator for 2,800,000 cycles. Another adjustment is then made for zero beat with the nearest harmonic in the other direction. This will give another setting corresponding to 2,900,000 cycles. These two points will be Xed with great precision. The unknown frequency can then be determined by interpolation.
To produce an output of known frequency the process is very similar. If it is desired to produce an output of 2,835,000 cycles, say, the settings of the vacuum tube oscillator for 2,800,000 cycles and 2,900,000 cycles are found by comparison with the corresponding harmonics of the crystal oscillator, and the setting for the desired frequency found by interpolation. The known frequency output is taken olf through inductance 6 (Fig. 1). If straight line frequency control is used, the interpolation may be made with greater accuracy and facility.
What I claim is: Y
1. A crystal calibrated wave meter comprising an electric oscillator, a crystal oscillator, a detector, and means for receiving a wave of unknown frequency, in combination with means for impressing waves from said electric oscillator and said crystal oscillator on said detector, means for impressing the wave from said electric oscillator and said unknown wave on said detector, and means for observing a beat note produced in said detector.
2. The method of measuring the frequency of anV unknown wave in a calibrating instrument comprising means for receiving said unknown wave, a variable frequency electric oscillator, a crystal oscillator, a detector and a signal indicator, which comprises impressing said unknown wave anda wave from said electric oscillator on said detector and adjusting the frequency of the wave from the electric oscillator for a zero beat in said signal indicator, impressing waves from said electric oscillator and said crystal oscillator on said detector and again adjusting the frequency or the wave from the electric oscillator for a zero beat in the signal indicator for the two harmonics of the crystal oscillator nearest to the frequency of the unknown wave, and interpolating between said last adjusted frequencies to determine the frequency of the unknown wave corresponding to the rst adjusted frequency.
3. The method of producing a wave of known frequency with'a device comprising a Variable frequency electric oscillator, a crystal oscillator, a
detector and a signal indicator, which comprises I impressing waves from said electric oscillator and said crystal oscillator on said detector and adjusting the frequency of the wave from the electric oscillator for a zero beat in said signal indicator between the two nearest harmonics of the crystal PHILANDER H. BETTS
US459772A 1930-06-07 1930-06-07 Constant frequency apparatus Expired - Lifetime US1947182A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2471432A (en) * 1944-08-11 1949-05-31 Lewis F Jaggi Wavemeter to calibrate panoramic receivers
US2603742A (en) * 1945-05-31 1952-07-15 Roy E Larson Electrical apparatus for testing radio equipment
US2763836A (en) * 1950-12-29 1956-09-18 Gilbert M Bullock Frequency measuring receiver

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2471432A (en) * 1944-08-11 1949-05-31 Lewis F Jaggi Wavemeter to calibrate panoramic receivers
US2603742A (en) * 1945-05-31 1952-07-15 Roy E Larson Electrical apparatus for testing radio equipment
US2763836A (en) * 1950-12-29 1956-09-18 Gilbert M Bullock Frequency measuring receiver

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