USRE16372E - fessenden - Google Patents

fessenden Download PDF

Info

Publication number
USRE16372E
USRE16372E US16372DE USRE16372E US RE16372 E USRE16372 E US RE16372E US 16372D E US16372D E US 16372DE US RE16372 E USRE16372 E US RE16372E
Authority
US
United States
Prior art keywords
sound
sounds
time
recorded
received
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
Publication date
Application granted granted Critical
Publication of USRE16372E publication Critical patent/USRE16372E/en
Expired legal-status Critical Current

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S1/00Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith
    • G01S1/72Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith using ultrasonic, sonic or infrasonic waves

Definitions

  • My invention relates to acoustic methods and apparatus, and more particularly to locating the direction of sound sources, and still more particularly-to submarine signalling.
  • My invention has for its object increased efliciency of acoustic methods and apparatus, and more particularly increased efficiency in locating the direction of sound sources, and'still more particularly increasing the efliciency of submarine signalling,
  • the sounds whose direction it is desired to determine are not received directly, but are recorded and then reproduced, and advantage is taken of the fact that by so doing it becomes possible to vary the time of reproduction of a sound heard in one, receiver relatively to the time of reproduction of the sound heard in a second receiver.
  • Figure 2 being an elevation of an alternative member described below.
  • 14 represents an oil tank in a destroyer.
  • 11 and 12 are receivers of any suitabletype, for example, oscillators.
  • the oscillator armatures are connected by the leads 18 and 19, to the recorders, 23, 24, of, a telegraphophone. 21, 22,are the magnetic wires of the telegraphophone, driven as shown by two wheels mounted on the shafts 20, 20' and driven by the motors 80,
  • 25 26 are reproducers connected as shown to an am lifier 28, and the amplified signals are ed .ferent instants of time, their reproduction I I from the amplifier as shown to the two ear phones of the head telephone 29.
  • Both reproducers are capable of adjustment toward and fromthe recorders, 26 and I producers as described below, position being accomplished travelling at the same s -corder 28 before it angle on a scale 27 showing two positions of one of the rethe changes in I by set screws 25', 27' respectively, arranged to operate in a well own manner.
  • the sound comes from the 'on of the upper left hand corner of the figure, it will be lator 11 before it is received by the oscillator 12,"and will be recorded by the reis recorded by the reeo'rder 24.
  • the reproducer of the sound received by the oscillator-'12 must be shifted towards the recorder 24 into the position shown at 26, andthe amount of the shifting may be used to determine the exact direction of the sound.
  • a disc as shown at 40, Figure 2
  • This has the advantage of simlglicity of construction and gives increased e ciency and accuracy.
  • the magnetic recording material should preferably travel at a speed of approximately three thousand feet 'per minute, if the best results are to be obtained, though good results may be obtained with speeds considerably less or.
  • 50 is a wireless antennaoperatively connected to a wireless receiving circuit 46.
  • 47 is an alternating 51 is a telegraph, key.
  • 45, 48 and 49 are switches which are normally closed and in the upward position, so as to connect the oscillator 12 with the recorder 24. and the reproducer 25 with the amplifier 28.
  • the apparatus for the method above described can be constructed so as to be ve compact, can be made very reliable, and to give direction with very great accuracy, and by adjusting the speed of the recording material, and in other ways, as by moving the recorders or reproducers as well as the magnetic material. can be made selective to sounds of any desired'frequency, butthis is not shown, as it is described and claimed in another application.
  • the apparatus is also little afiected by disturbing noises.
  • the method and apparatus may be used producing bodies, such as the bottom of the sea, or icebergs.
  • W1 1 be connected to the recorder 24 and the oscillator- 12 will be cut out.
  • a wireless. signal and-a submarine signal may be emitted simultaneously at intervals of say 101' 2 minutes, by means and methods described in another'application.
  • the wireless signal sent out from the lightship will be received on the antenna 50, and recorded by the recorder 24, and the submarine signal sent out at the same instant from the lightship may be received b the 2tscillator 11, and recorded by therecor er
  • the wireless signal will be received practically instantaneously, whereas the submarine signal will travel at the rate of about forty-four hundred feet per second, the wire less signal'will be recorded by the recorder 24 before the submarine signal is recorded by the recorder 23, and hence the re reducer 26 will have to be shifted away rom the recorder 24, or else the reproducer 25 shifted towards the recorder 23, in order that both signals may be heard simultaneously in the ear pieces of the receiver 29, and the amount of relative shifting of the reproducers 26 and 25 will depend upon the distance of the lightship from the vessel carrying the re- ,cexving'apparatus, and this distance can be read off on the scale 31, the scale 31 being calibrated experimentally so as to read distance directly, preferably in tenths of miles.
  • the ap aratus may be used for takin soundin the distance of lcebergs by echo, by throwing the switch 48, which is normally thrown. upwards, to the right, so as to put the alternator 47 in series with ,the recorder. 24'and the oscillator 12, the switch 45 being, also in'its normal or upward position.
  • a submarine signal will be sent out by the oscillator 12 and at the same instant recorded by the recorder 24.
  • the sound so produced will travel outwards, and on striking any reflecting ob- ]ect, such as the bottom of the sea, or an lceb'er will be returned, and after a time, depen ing upon the distance of the reflecting ob ect and the velocity of sound in the water, wil reach the oscillator 11, acting as a receiigr, and will be recorded by the recorder
  • the reproducers 25 and 26 will be recorded by the recorder The reproducers 25 and 26.
  • the reproducer 26 may then be shifted relatively to each other, for example, the reproducer 26 shifted aw'ay'from 24, and the reproduce'r 25 shifted towards 23/ until the sound of the signal sent out from 12 and the echo received back will be heardat y echo, or determining the same instantof time, and the amount 4 of shifting will as before he a measure of the distance of the reflecting object, and the scale 31 may he graduated so as to read the depth of the sea or the distance of the iceberg directly in feet or yards or fathoms.
  • This'method of taking soundings has the advantage that soundings maybe taken while the vessel is at full speed. It is also much more accurate than any other known method, as applicant has found by experiment that the instant of coincidence of two sounds may be determined with an accuracy. of one five thousandth of a second, which corresponds to an accuracy of six inches intaking the sounding.
  • the apparatus is used for de-- termining direction as described in the first art of the specification.
  • the sound received y the oscillator 11 will be transmitted di rectly through the'amplifier 28, to the head phone 29, instead of reaching the head phone 29 from the reproducer 25.
  • the oscillator 11, and be recorded by the recorder 24, and hence the reproducer 26 can be shifted to such a position that the a I 7 sound received by the oscillator 12 and the sound received by the oscillator 11 can be heard simultaneously in the head phone 29, and the amount of shifting will as before determine the direction.
  • an acoustic apparatus comprising two sound receivers, two sound recorders, one connected to each sound receiver; two sounds records, two sound reproducers, and means for varyin the times of reproduction of the records re atively to each other.
  • Acoustic apparatus comprising two sound receivers, two sound recorders, one connected .to each sound receiver; two sound records, two'sound reproducers, and means for varying the times of re roduction of the records relatively to eac other, and a scale for indicating the amount of relative variation.
  • a method of locating the direction of a source of vibration which consists in measuring the time interval between the re- 'sponse thereto of two similar vibration-responsive current-varying devices by relatively varyin the time interval between the reco and reproducing of effects by such devices to bring the electrical variations caused by the reproductions into phase coincidence where y the direction of the ,source 0 vibration may be deduced from of the time intervals between the recording and reproducing.
  • a method of measuring small time ilk .tervals which consists in successively gen- 'erating in a plurality of electrical circuits similar waves spaced. by the time intervals to be measured, simultaneously. recordin the efi'ects produced by such waves and 'adjustreceiving the sound a sound at a time later than thewhich consists in receiving ords until the reproduced waves are in phase coincidence whereby the time adjustment serves as a measure of the time interval.
  • a method of measuring the depth of a body of water which comprises the establishment of a signal producer and a receiver at a distance from each other, causing sounds from the producer to be directed to the bottom of the water and reflected therefrom and to be received by said receiver and transmitted to an indicator and causing said signal from said producer to be sent to said indicator, and synchronizing the arrival of the signals at the indicator, and measuring the depth by the adjustment necessary for causing synchronism.
  • the method of determining distance consisting in sending out a sound impulse, imparting this impulse directly to a primary receiving system leading to one ear of an observer, taking up the reflected impulse in a secondary receiving system leading to the other ear of the observer, and retarding the impulse in the primary receivin system so as to cause it to coincide with the reflected impulse as to time of arrival at the ears of the observer and measuring the distance by the amount of retardation.
  • a sound receiver In a device for measuring distance with the aid of a sound producer, a sound receiver, two indicators, means for conducting a direct impulse of the sound producer to one of said indicators, means for conducting the reflected impulse received by said sound receiver to the, other of said indicators, adjustin meansto synchronize the impulse at the indicators, and means to indicate the magnitude of the distance to be measured.
  • a method formeasuring distances by means of reflected sound impulses comprising sending out an electrically produced sound impulse, imparting a corresponding impulse to a traveling recording member, reproducing the recorded impulse in one recelving member, reproducing the reflected impulse in another receiving system, adjusting the time of travel ofthe recorded impulse so as to cause its reproduction cide with the reflected impulse in the second receiving system, and measuring the distance by means of the necessary adjustment. 14.
  • a method of measurin distances by means of reflected sound impu ses comprising coin--- ing sending out a sound impulse, imparting a corresponding direct impulse to one recei member, receiving the reflected impulse in another receiving system, retarding the direct impulse so as to cause its reproduction to coincide with the reflected impulse in the second named receiving system and measuring the distance by means of necessary retardation.

Landscapes

  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Measurement Of Velocity Or Position Using Acoustic Or Ultrasonic Waves (AREA)

Description

June 29, 1926. Re. 16,372
R. A. FESSENDEN ACOUSTIE METHOD AND APPARATUS Orizinal le April 28 1919 AW L/HEP Ana/nee fis'uas' 2.
INVENTOR.
ATTORNEYS.
June 29, 1926.
UNITED STATES PATENT OFFICE.
A. PESSENDEN, 0P CHESTNUT HILL, MASSACHUSETTS, ASSIGNOB TO- SUI- 1mm SIGNAL COMPANY, 01 POBTLAN D, IAINE, A CORPORATION 0] mm ACOUSTIC METHOD AND APPARATUS.
Original Io. 1,468,818, dated lay 1, ma, mm m. 203,201, fled April as, 1919. a umumm reissue fled April 9, 1925. Serial Io. 21,092.
My invention relates to acoustic methods and apparatus, and more particularly to locating the direction of sound sources, and still more particularly-to submarine signalling.
My invention has for its object increased efliciency of acoustic methods and apparatus, and more particularly increased efficiency in locating the direction of sound sources, and'still more particularly increasing the efliciency of submarine signalling,
andv locating the direction and position of sources of submarine sounds.
The accompanying drawing forming a part of the specification shows'i'n Figures 1 and 2, partly diagrammatically, means suitable for carrying out my invention.
1 Heretofore the direction and position of sources of sound have been determined in a number of ways, for example,
(a) Mounting two receivers on opposite sides of a body, such as a ship, and turning the body until the sound is heard equally well 1n both receivers (.b) Using two receivers, and turning them so that the phases of the sounds received in each receiver are coincident or opposite to each other (U. S.-Patent 1,270,398, October 7, 1915).
(a) By reflection (U. S. Patent 1,240,328, Jan. 15,1917).
((1) By using two receivers and cutting downthe strength of the sounds received in one to equality to those heard in the other.
' (e) By varying the phase of the currents produced in two receivers by varying the inductance or capacity of the receiver cir- 'cuits (U. S. application).
, directly, the sounds whose direction it is (f) By recei 'ng'the sounds on a number of receivers separated by sound screens, and noting-on which receiver the sound is the loudest. I I
(g) By varying the relative len h of two air columns operatively connecte transmit to the ear, either directly or indesired to determine. I
(h) By other methods forming the subjectbf other applications. The above methodsihaveall been useful, but. the method described in the present specification has'certainadvantages, more soas tO' particularly as regards accurac sim licit reliability, and adaptability. p
In the resent method the sounds whose direction it is desired to determine are not received directly, but are recorded and then reproduced, and advantage is taken of the fact that by so doing it becomes possible to vary the time of reproduction of a sound heard in one, receiver relatively to the time of reproduction of the sound heard in a second receiver.
Consequently if two receivers are located at a distance from each other, 'for exam le, on opposite sides of a ship, or preferably in an oil tank or ballast tank in a ship, it is possible by varying the times of reproduction of the sounds recorded from each of the two receivers, to make the reproduction occur at an desired phase or time relation,
paratus adapted to carry out my invention;
Figure 2 being an elevation of an alternative member described below. a
In Figure 1, 14 represents an oil tank in a destroyer. 11 and 12 are receivers of any suitabletype, for example, oscillators. The oscillator armatures are connected by the leads 18 and 19, to the recorders, 23, 24, of, a telegraphophone. 21, 22,are the magnetic wires of the telegraphophone, driven as shown by two wheels mounted on the shafts 20, 20' and driven by the motors 80,
30 at a'predetermined constant speed or otherwise as referred to below. 25, 26 are reproducers connected as shown to an am lifier 28, and the amplified signals are ed .ferent instants of time, their reproduction I I from the amplifier as shown to the two ear phones of the head telephone 29.
Both reproducers are capable of adjustment toward and fromthe recorders, 26 and I producers as described below, position being accomplished travelling at the same s -corder 28 before it angle on a scale 27 showing two positions of one of the rethe changes in I by set screws 25', 27' respectively, arranged to operate in a well own manner.
and 16 are perforated tubes connected throughthe cock 17, to asource of compressed air, and these tubes are immersed so as to be just below the level of the oscillators 11 and 12.
In the practical operation of the apparatus, a sound coming from dead ahead and striking the oscillators Hand 12 will affect them at the same instant, and the sounds will be recorded simultaneously by therecorders 23, 24, and since the wires 21, 22'. are ed, they will be P ducer 25, and a reproducer located in the position 27, and will consequently be heard simultaneously and in .the same phase by the operator listening in to the head phone 29.
If, however, the sound comes from the 'on of the upper left hand corner of the figure, it will be lator 11 before it is received by the oscillator 12,"and will be recorded by the reis recorded by the reeo'rder 24.
Consequently, in order that the reproductions of the sounds may be heard simultaneously, the reproducer of the sound received by the oscillator-'12 must be shifted towards the recorder 24 into the position shown at 26, andthe amount of the shifting may be used to determine the exact direction of the sound.
This is most conveniently done by producing sounds at difierent 'known angles with the fore and aft line of the ship. maintaining the reproducer 25 in a fixed position, shifting the reproducer 26 until the sound is reproduced in both reproducers simultaneously. and marking ofi the known 31: and repeating the procealuntil all the desired angles are on the sea e.
Where only two oscillators are used, there will sometimes bedificulty in determining whether the source of sound is a certain number of degrees ahead of the ships beam, equal number of degrees astern of the s 1p s of sound is" ahead.
Similarly by turning the c'o'ck 17 in the other direction. so that the air bubbles do not come off from the perforated pine15.
but do come of from the perforated pipe 16, he will find that the sound is not weakroduced simultaneous y by the repro received by the oscilbeam. To determine this the operator turns the cock so as to emit air bubbles ened and consequently he is doubly able to assure himself coming from .a point ahead.
In place of using magnetic wires,running over pulleys, as shown in Figure 1, formcording the sounds, a disc, as shown at 40, Figure 2, may be used, either the whole disc being made out of magnetic material, or having a magnetic rim 41. This has the advantage of simlglicity of construction and gives increased e ciency and accuracy.
It is preferred ing material, whether wire or disc, be run at a predetermined speed, and it is also preferable that this s ed should bear a definite relation to the istance apart of the two oscillators 11 and 12. By changing the relative speeds of the motors 30, the relative speeds of the wires 21 and 22 will be changed.
I have found by experiment that if the oscillators are five feet apart, the magnetic recording material should preferably travel at a speed of approximately three thousand feet 'per minute, if the best results are to be obtained, though good results may be obtained with speeds considerably less or.
greater than three thousand feet per minute. The telegraphophone is not shown in full,
as it is a well-known article of commerce,
of the fact that the sound is that the magnetic record- I and hence the wiping out magnet, starting switches,etc., are not shown.
50 is a wireless antennaoperatively connected to a wireless receiving circuit 46. 47 is an alternating 51 is a telegraph, key.
45, 48 and 49 are switches which are normally closed and in the upward position, so as to connect the oscillator 12 with the recorder 24. and the reproducer 25 with the amplifier 28.
It is obvious that in reproducers relatively to each other, they may be maintained fixed, and the speed of the two wires 21, 22, varied relatively to each other.
The apparatus for the method above described can be constructed so as to be ve compact, can be made very reliable, and to give direction with very great accuracy, and by adjusting the speed of the recording material, and in other ways, as by moving the recorders or reproducers as well as the magnetic material. can be made selective to sounds of any desired'frequency, butthis is not shown, as it is described and claimed in another application.
The apparatus is also little afiected by disturbing noises. I
The method and apparatus .may be used producing bodies, such as the bottom of the sea, or icebergs.
For example, if the switch 45, which is current dynamo, and.
place of varying the eratively connected to the antenna 50, W1 1 be connected to the recorder 24 and the oscillator- 12 will be cut out.
If a lightship be equipped with a wireless sendmg station and a submarine signal sending station, a wireless. signal and-a submarine signal may be emitted simultaneously at intervals of say 101' 2 minutes, by means and methods described in another'application. a V
, The wireless signal sent out from the lightship will be received on the antenna 50, and recorded by the recorder 24, and the submarine signal sent out at the same instant from the lightship may be received b the 2tscillator 11, and recorded by therecor er As the wireless signal .will be received practically instantaneously, whereas the submarine signal will travel at the rate of about forty-four hundred feet per second, the wire less signal'will be recorded by the recorder 24 before the submarine signal is recorded by the recorder 23, and hence the re reducer 26 will have to be shifted away rom the recorder 24, or else the reproducer 25 shifted towards the recorder 23, in order that both signals may be heard simultaneously in the ear pieces of the receiver 29, and the amount of relative shifting of the reproducers 26 and 25 will depend upon the distance of the lightship from the vessel carrying the re- ,cexving'apparatus, and this distance can be read off on the scale 31, the scale 31 being calibrated experimentally so as to read distance directly, preferably in tenths of miles.
Similarly the ap aratus may be used for takin soundin the distance of lcebergs by echo, by throwing the switch 48, which is normally thrown. upwards, to the right, so as to put the alternator 47 in series with ,the recorder. 24'and the oscillator 12, the switch 45 being, also in'its normal or upward position.
On'closing the key 51, fora short time,
i say a second, a submarine signal will be sent out by the oscillator 12 and at the same instant recorded by the recorder 24.
The sound so produced will travel outwards, and on striking any reflecting ob- ]ect, such as the bottom of the sea, or an lceb'er will be returned, and after a time, depen ing upon the distance of the reflecting ob ect and the velocity of sound in the water, wil reach the oscillator 11, acting as a receiigr, and will be recorded by the recorder The reproducers 25 and 26. may then be shifted relatively to each other, for example, the reproducer 26 shifted aw'ay'from 24, and the reproduce'r 25 shifted towards 23/ until the sound of the signal sent out from 12 and the echo received back will be heardat y echo, or determining the same instantof time, and the amount 4 of shifting will as before he a measure of the distance of the reflecting object, and the scale 31 may he graduated so as to read the depth of the sea or the distance of the iceberg directly in feet or yards or fathoms.
This'method of taking soundings has the advantage that soundings maybe taken while the vessel is at full speed. It is also much more accurate than any other known method, as applicant has found by experiment that the instant of coincidence of two sounds may be determined with an accuracy. of one five thousandth of a second, which corresponds to an accuracy of six inches intaking the sounding.
Whilefor most purposes applicant prefeis to use two recorders and two reproducers,
one recorder and one reproducermay be used. v v
For example, if the switch 49, which is normally in the upward position, be thrown downward, while the switches 48 and 45 are maintained in their normal position, i. e.,
upwards, and the apparatus is used for de-- termining direction as described in the first art of the specification. the sound received y the oscillator 11 will be transmitted di rectly through the'amplifier 28, to the head phone 29, instead of reaching the head phone 29 from the reproducer 25.
But a sound coming from the direction of the upper right hand part of the figure will reach'the oscillator 12 before it reaches,
the oscillator 11, and be recorded by the recorder 24, and hence the reproducer 26 can be shifted to such a position that the a I 7 sound received by the oscillator 12 and the sound received by the oscillator 11 can be heard simultaneously in the head phone 29, and the amount of shifting will as before determine the direction.
claim: 1. The method of determining the interval of time 'elap sing between the receipt of sounds at two points at a distance from each.
other which consists in receiving the sound at each of said points. recording the sound received at one of said points, reproducing the recorded sound at a time later than the time of making the record and comparing the reproduced sou'nd from said point with the sound received at the other point.
2. In a method of determining the interval of time elapsing between the receipt of the recorded sound at a time later than the time of making the record and varying the time interval between the making of. the record and the reproduction of the sound.
3. The method of determining the intcr-v Having now described my invention, I
A the recorded sound at a the relation val of time elapsing between the receipt of sounds at two points at a distance from each other which consists in at each of said points,
recording the sound received at one of said points, reproducing time late'rthan the time of making the record andaleterniining the time interval between the making of the record and the reproduction of the sound.
4. In a method of determining the interval of time elapsing between the receipt of sounds at two points at a distance from each other which consists in'receiving the sound at each of said points. recording the sound received at one of said points, reproducing the recorded time of making the record, and adjusting the time interval between the making of the record and the reproduction of the sound until the sound heard from each of the two points produces an indicationat the same instant 0 time. i v
5. The method of determining the direction of sounds, the sounds by means of two receivers loca at a distance from each other, recording the sounds received by the receivers, reproducing the recorded sounds, varying the time of reproduction of the recorded sounds relatively to one another, and determining the direction of the source of sound from the amount of said variation. 1
6. In an acoustic apparatus comprising two sound receivers, two sound recorders, one connected to each sound receiver; two sounds records, two sound reproducers, and means for varyin the times of reproduction of the records re atively to each other.
7. Acoustic apparatus comprising two sound receivers, two sound recorders, one connected .to each sound receiver; two sound records, two'sound reproducers, and means for varying the times of re roduction of the records relatively to eac other, and a scale for indicating the amount of relative variation.
8 A method of locating the direction of a source of vibration which consists in measuring the time interval between the re- 'sponse thereto of two similar vibration-responsive current-varying devices by relatively varyin the time interval between the reco and reproducing of effects by such devices to bring the electrical variations caused by the reproductions into phase coincidence where y the direction of the ,source 0 vibration may be deduced from of the time intervals between the recording and reproducing.
9; A method of measuring small time ilk .tervals which consists in successively gen- 'erating in a plurality of electrical circuits similar waves spaced. by the time intervals to be measured, simultaneously. recordin the efi'ects produced by such waves and 'adjustreceiving the sound a sound at a time later than thewhich consists in receiving ords until the reproduced waves are in phase coincidence whereby the time adjustment serves as a measure of the time interval.
10. A method of measuring the depth of a body of water which comprises the establishment of a signal producer and a receiver at a distance from each other, causing sounds from the producer to be directed to the bottom of the water and reflected therefrom and to be received by said receiver and transmitted to an indicator and causing said signal from said producer to be sent to said indicator, and synchronizing the arrival of the signals at the indicator, and measuring the depth by the adjustment necessary for causing synchronism.
11. The method of determining distance consisting in sending out a sound impulse, imparting this impulse directly to a primary receiving system leading to one ear of an observer, taking up the reflected impulse in a secondary receiving system leading to the other ear of the observer, and retarding the impulse in the primary receivin system so as to cause it to coincide with the reflected impulse as to time of arrival at the ears of the observer and measuring the distance by the amount of retardation.
12. In a device for measuring distance with the aid of a sound producer, a sound receiver, two indicators, means for conducting a direct impulse of the sound producer to one of said indicators, means for conducting the reflected impulse received by said sound receiver to the, other of said indicators, adjustin meansto synchronize the impulse at the indicators, and means to indicate the magnitude of the distance to be measured.
13. A method formeasuring distances by means of reflected sound impulses, comprising sending out an electrically produced sound impulse, imparting a corresponding impulse to a traveling recording member, reproducing the recorded impulse in one recelving member, reproducing the reflected impulse in another receiving system, adjusting the time of travel ofthe recorded impulse so as to cause its reproduction cide with the reflected impulse in the second receiving system, and measuring the distance by means of the necessary adjustment. 14. In a method of measurin distances by means of reflected sound impu ses, compris to coin-- ing sending out a sound impulse, imparting a corresponding direct impulse to one recei member, receiving the reflected impulse in another receiving system, retarding the direct impulse so as to cause its reproduction to coincide with the reflected impulse in the second named receiving system and measuring the distance by means of necessary retardation.
REGINALD A. FESSEND EN.
US16372D fessenden Expired USRE16372E (en)

Publications (1)

Publication Number Publication Date
USRE16372E true USRE16372E (en) 1926-06-29

Family

ID=2077951

Family Applications (1)

Application Number Title Priority Date Filing Date
US16372D Expired USRE16372E (en) fessenden

Country Status (1)

Country Link
US (1) USRE16372E (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5034930A (en) * 1966-02-04 1991-07-23 The United States Of America As Represented By The Secretary Of The Navy Passive ranging sonar system

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5034930A (en) * 1966-02-04 1991-07-23 The United States Of America As Represented By The Secretary Of The Navy Passive ranging sonar system

Similar Documents

Publication Publication Date Title
US1864638A (en) Method and means for the observation and measurement of the speed of a vessel by directed beams of ultra-audible waves
US1973673A (en) Sound or air wave apparatus
Luskin et al. Precision measurement of ocean depth
JPS58213271A (en) Method and device for telemeter-measuring relative position of underwater object to carrying body by sound wave
US2865196A (en) Apparatus for measurements concerning the velocity of propagation of waves, and in particular sound waves
US2910665A (en) Radio acoustic ranging system
US4104912A (en) System for taking current-metering measurements
US4086560A (en) Secret depth sounder
US2536771A (en) Subaqueous sound transmission system for object detection
US3267416A (en) Ice profiling sonar system
US1983254A (en) Method and apparatus for distance finding
US2480561A (en) Hydrofoil depth control
US1785307A (en) System and method of communication
USRE16372E (en) fessenden
US3116471A (en) Radio sonobuoy system
US4308749A (en) Device for measuring in real time sea currents in deep water
US1636502A (en) Method and apparatus for determining distance by echo
US1453316A (en) Acoustic method and apparatus
GB798105A (en) Improvements in or relating to apparatus for determining the depth of an object in water
US1547574A (en) Apparatus for sounding
US2997689A (en) Distance measuring apparatus
US2418490A (en) Distance and direction measuring system
US3939463A (en) Acoustic transponder navigation system
US2958846A (en) Recording ocean depth
US913528A (en) Signaling system.