US1565505A - Radiotransmitter - Google Patents

Radiotransmitter Download PDF

Info

Publication number
US1565505A
US1565505A US731906A US73190624A US1565505A US 1565505 A US1565505 A US 1565505A US 731906 A US731906 A US 731906A US 73190624 A US73190624 A US 73190624A US 1565505 A US1565505 A US 1565505A
Authority
US
United States
Prior art keywords
relay
circuit
power
tubes
switch
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 - Lifetime
Application number
US731906A
Other languages
English (en)
Inventor
Francis M Ryan
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
AT&T Corp
Original Assignee
Western Electric Co Inc
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Western Electric Co Inc filed Critical Western Electric Co Inc
Priority to US731906A priority Critical patent/US1565505A/en
Application granted granted Critical
Publication of US1565505A publication Critical patent/US1565505A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B1/00Details of transmission systems, not covered by a single one of groups H04B3/00 - H04B13/00; Details of transmission systems not characterised by the medium used for transmission
    • H04B1/02Transmitters
    • H04B1/04Circuits
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02HEMERGENCY PROTECTIVE CIRCUIT ARRANGEMENTS
    • H02H7/00Emergency protective circuit arrangements specially adapted for specific types of electric machines or apparatus or for sectionalised protection of cable or line systems, and effecting automatic switching in the event of an undesired change from normal working conditions
    • H02H7/20Emergency protective circuit arrangements specially adapted for specific types of electric machines or apparatus or for sectionalised protection of cable or line systems, and effecting automatic switching in the event of an undesired change from normal working conditions for electronic equipment
    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03FAMPLIFIERS
    • H03F1/00Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
    • H03F1/52Circuit arrangements for protecting such amplifiers
    • H03F1/54Circuit arrangements for protecting such amplifiers with tubes only

Definitions

  • the present invention relates to wave transmission systems and particularly to radio transmission systems.
  • the invention has particular application in radio transmitting, systems involving a considerable amount of high frequency en ergy.
  • vacuumtube amplifiers to increase the radio frequency power to the level required.
  • control systems which will permit the necessary circuit changes to.
  • An object of the invention is to effect the necessary controls of a vacuum tube system in a simple and efficient manner.
  • a related object is to supply the operating voltages to vacuum tube circuits and similar apparatus in an efiicient manner.
  • a polyphase power distributing circuit for supplying the anode circuits of space discharge tubes.
  • An automatically operating starting circuit for causing the successive units of a tube system to start in predetermined seustment of a radio transmitter to another wave length adjustment.
  • Restart features whereby after a shift in the circuit adjustments, the system is caused immediately and automatically to take up. efiicient operation on the basis of the new ad ustment; and various features concerned in the operation and control of the system, as will appear more fully hereinafter.
  • the radio frequency power developed in the antenna may amount to many kilowatts, requiring that potentials of several thousand volts be supplied to the tube circuits.
  • Fig. 1 The portion of the system shown on Fig. 1 is designated the low frequency panel, that on Fig. 2 the high frequency panel, that on Fig. 3 the power panel and that of Fig. 4 the power amplier panel. It is to be understood, of course, that in actual practice the apparatus may be distributed in this or in an other manner upon any desired number 0 panels, or otherwise disposed.
  • a telegraph key 3 at station A and a similar one at station B are also supplied for controlling the radio station in accordance with telegraph messages, in a'manner to be described hereinafter.
  • the telephone apparatus is connected by the aid of suitable switching devices to be described later to the primary of the repeating coil 5, the secondary of which feeds into the voice amplifying circ'uit VA of Fig. 1.
  • This amplifier comprises in the specific circuit illustrated two stages of amplification, the first comprising a three-element vacuum tube 6 of usual construction and the second stage comprising the two tubes 7 and 8 1n parallel.
  • the amplified output of the amplifier VA is supplied to the late circuits of the modulator M, which is s own as comprising a pair of three-element vacuum tubes 28 and 29 connected in parallel.
  • the grids of the tubes 28 and 29 are supplied by an oscillator 0 comprising a three-element vacuum tube 27 provided with the pro er "circuits for causing it to generate radio 'requency oscillations.
  • Modulation of these radio frequency oscillations by the amplified speech is effected in the modulator tube 011- cuit M, and the resulting modulated waves are su plied to the grid circuits of the power ampli er PA.
  • the amplified modulated waves from the power amplifier PA are supplied through suitable coupling circuits to the transmitting antenna TA.
  • the heavy line is used to indicate plate current supply circuits; and the heavy broken line is used to indicate grid biasing circuits.
  • the oscillator 0 comprises, as stated, the
  • tube 27 and the tuned circuit generally indicated at 34 This comprises an inductance 35 to the opposite terminals of which the grid and anode, respectively, of tube 27 are ada ted to be connected, and variable capacities 36 and 37 connected in series across inductance 35 with the filament of tube 27 connected between the capacities.
  • an antiresonant circuit 38 Bridged across the radio frequency output circuit of the modulator M is an antiresonant circuit 38 comprising capacity 39 and inductance 43 connected in parallel between the lead 42 and ground.
  • the purpose of this anti-resonant circuit is to improve the transmission characteristics of the circuit as will be indicated more fully hereinafter.
  • Actuation of the handle WL to change the frequency of the oscillator also changes the tuning of circuit 38.
  • the antenna circuit comprises the loading inductance 44 connected adjustably to a parallel circuit having one branch composed of the tuning inductance 45 and the capacity 46 in series to ground and the other branch comprising the capacity 47.
  • the radio frequency output circuit from the power amplifier passes through the blocking condenser 48 to a. variable tap on tuning inductance '45.
  • the path to ground from the power amplifier PA thus includes an adjustable amount of inductance 45 and capacity 46 and by varying the adjustments provided for inductance and condensers 46 and 47' by means of the wave length handwheel VVL the antenna tuning may be changed and any suitable coupling may be obtained, as will be explained more in detail hereinafter, the switches WL v and VL, are mechanically connected so as to move together so as to insure that the oscillator tuning,-the' coupling, and the. antenna tuningall have the proper relation for satisfactory operation.
  • the power supply for energizing all of the vacuum tube circuits is derived primarily from the three-phase generator 20, Fig. 1. This eneiator supplies power directly to the primary 40, from the secondary 50 of which are derived the anode potentials for the power amplifier PA.
  • the operating voltages for all of the vacuum tubes on the low frequency panel and on the high frequency panel are supplied from motor generator sets indicated in 1 ig. 2 supplied with power from generator 20. These comprise the motors 51 and 52 and the generators driven thereby, of
  • the primary 40 of the power transformer is shown delta connected, although it might have been some other suitable type-of connection, while the secondary 50 is shown as distributedY connected. This is also called an interconnected star arrangement.
  • the primary winding shown in the drawing in the. vertical position would have as its secondary windings the two half coils of secondary 50 that are in the vertical position, these three windings being placed on the same core.
  • each limb of the transformer core carries, in addition-to a primary w1nd1ng, two secondaries, one from each of two phases.
  • Each secondary circuit or phase. is connected to one of the rectifiers, so that only direct current flows in the secondary wind-- ings.
  • the direct current in one of the two secondary windings on one transformer leg just ncutralizes that in the other winding so that there is no direct current flux from the rectified .current in any of the trans:
  • Condenserz59' is bridged across the amplifier plate sup 1y leads and forms a low impedance path or these harmonics and also for speech frequency components present in the power amplifier plate current.
  • Radio frequency inductance 49 inserted between the direct current ground and the antenna ground, is not essential but is convenient in case a counterpoise is to be used in place of the antenna ground. In such case if the alternating current branch of the "paver amplifier were connected directly to the filament ground, a considerable portion of the antenna current would be shunted around the counterpoise capacity. Choke 4:9 prevents this but readily passes the smaller tube-output alternating current.
  • the cathodes of the power amplifier and of the rectifier tubes 56, 57 and 58 are heated by alternating current obtained by transformers from the three phase power supply leads 61, 62 and 63.
  • the primary windings of the filament heating transformers are connected across the leads 1n rotation to distribute the load equally among the phases.
  • the alternating current and the direct cur-- rent voltages developed in a radio trans- Jnitter of the form being described amount to, many thousand volts in a transmitter of considerable power output.
  • the power I amplifiertubes and also the rectifier .tubes were of the type in which the anodes are cooled bycirculating water.
  • the power In order to prevent injury "to the tubes, it is essential that the power be shut off from the tubes immediately in case of failure in the cooling system, or 1n case of an overload due to a short circuit or a wrong adjustment of the circuit. It is also important to apply the v potentials to the tube elements in the proper sequence.
  • a group of relays is provided on the low frequency panel cooperating with a second group of relays on the high frequency panel for enabling the starting operations to take place in sequence from a sin 'le control button. This obviates the necessity of the attendant watching meters or alarm devices and exercising a succession of controls, and by simplifying the .control procedure makes the system adapted for starting and stopping from an outlying station.
  • the start control circuit is arranged for actuation from the start control button in conjunction with certain safety circuits repairs, etc.
  • the leads 17 and 18 are energized from-the generator 20 and these leads supply operating voltage for the various relay circuits.
  • the lead 31 for energizing switching relay 13 passes through contacts on the wave length controls WL and VVL and also through certain relay contacts to be described hereinafter, so that relay 13 is deenergized and power from the generator 20 is cut off from the supply leads 61, 62 and 63 unless all of the series. contacts in lead 31 are closed.
  • the lead 32 which supplies locking current-for the relay 14 contains a number of overload contacts in series, so that in case extraordinary voltages are produced at certain critical points in the system, lead 32 is opened, causing relay 14, to deenergize and open the circuit of switching relay 13 and certain relays on the high frequency panel cutting oflz' the power supply from the entire set. Similar provision is made for shutting 01f the power under control of door switches which are indicated diagrammatically in Figure l, and from water pressure and temperature indicators as will be described later on.
  • Relay 11 applies power from the source 20 to the motors 51 and 52, causing them to start up the various generators. 53, 54 and 55 for supplying filament, anode and grid polarizing to the tubes as described hereinbe ore.
  • the field of the filament current generator 53 is normally closed through resistances 66, 67 and 68, this machine being self-exciting. After it is set into motion therefore, voltage is.'developed across the filament heating leads '71 and 72, causing after a time, the energization of the marginal relay 12 which is slow to energize.
  • Generator 55 also develops its full load voltage across the grid polorizing leads-73 and 74, causing the application of grid polarizin potential to all of the tubes throughout are system. A smoothing condenser, 97, is shown connected across these leads. Since the field circuit of generator 54 is open at this time, at the right hand front contact of relay 24, no anode voltage is applied to the tubes on the low frequency and high frequency panels.
  • One or the other of the motors 51 or 52 is assumed to drive a suitable pump for circulating water through the cooling system for the power amplifier and rectifier tubes.
  • Relay 1 closes at its front contact a circuit in parallel with its own circuit for relay 19 through leads 17 and 18.
  • Relay 19 is slow to energize and before it has time to break its right hand back contact, a circuit for relay 14 is closed from lead 17, through one of the door switch contacts, winding of relay 14, resistance 76, right hand back contact and armature of relay 19 to lead 18. It will be noted that relay 14 was shunted through the back contact of relay 15 up to-the time that relay 15 became energized.
  • Relay 19 closes a locking circuit for itself through its left hand armature and front contact.
  • Relay 14 closes a locking circuit for itself through its left hand armature and front contact and lead 32, provided the overload relays 77', 78 and 41 are not energized.
  • relay 19 may be depressed to close a circuit from conductor 18, normal contacts of relays 41, 78, 77 and conductor 32, resistance 76, winding of relay l4, door switch. contact, to conductor 17, thus starting the system in the manner described.
  • Closure of key 122 shunts relay 14 causing it to deenergize and shut the power off from the power panel and power amplifier in the manner already described.
  • Relay 14 being energized and locked as de scribed, a circuit is closed through relay 13 from lead 17, winding of relay 13, right hand armature and front contact of relay 14, conductor 79, contact of relay 25 (this relay having been energized when the grid polarizing generator was started) conductor 31, contact on the power control handle PC, contact on the wave length switch VVL ,'to
  • relay 22 is energized from conductor 17, contact on the door switch, winding of relay 22, armature and contact of relay 21, lead 31 to conductor 18 as previously traced.
  • Relay 22 at its right hand contacts extends the plate current supply leads from generator 54 to the voice amplifier oscillator and modulator tubes and at its left hand contact closes a circuit for relay 23 extending from conductor 17, contact of the door-switch, left hand armature of relay 22, winding ofrelay 22- contact of relay 26, lead "31 to conductor 18 as previously traced.
  • lay 26 is an overload relay and under normal conditions remains unoperated.
  • Relay 23 in energizing closes a circuit at its left hand armature for maintaining relay 22 energized, thiscontact being inparallel with the contact-of relay 21 so long as relay 26 is deenergized. So long therefore. as there is no break in conductor 31 and no abnormal plate current to cause relay 26 to energir'te, (the door switch being assumed to remain closed), relays 22 and 23 remain locked up. Should either relay become deenergizcd, except for the auxiliary control buttons 123 and 124, it is impossible for it to reenergize without first deenergizing relay 21 which can only occur through a break in conductors 17 and 18. or in lead 31. I
  • Button 123 is an auxiliary starting button similar to 121, and when depressed enables relay 22 to be operated to start the high frequency panel supply system regardless of the energized condition of relay 2]. Also button 124 when depressed, momentarily opens the locking circuit for relays 22 and suddenly.
  • Relay 81 in energizing at its right hand contact closes a short circuit around resistance 66. At its left hand contact relay 81 connects the filaments of the voice amplifier tubes across the leads 71 and 72- causing the filaments of these tubes to become heated.
  • Resistance 66 is a compensating resistance to keep the filament voltage constant for the two load conditions corresponding to telephony and telegraphy.
  • the tubes 6, 7 and 8 are out of circuit when the set is used for. telegraph, the filament circuit for these tubes being opened at the left armature of relay 81, so that less load is placed on the filament heating generator than when telephoning.
  • relay 81 is energized, therefore, to include the filaments of tubes 6, 7 and 8 in circuit, the resistance 66 is shunted to increase the field excitation of generator 53 to keep its output voltage the same.
  • relay 24 in energizing establishes the field circuit for the plate current generator 54 through its right hand armature and contact across leads 71 and 721 At the same time relay 24, at itsleft hand contactbridges the resistance 67, in the field circuit of generator 53.
  • Generator 54 gets its field excitation from generator 53, so that when relay"? 24 cuts in the generator 54 it is necessary to increase the field excitation of generator 53 to keep its output voltage the same with the increased load on it.
  • an antenna which may be of the well known loop type or any suitable type and which will preferably be oriented or positioned to receive from the distant; radio station, but to be free of undue interferences from the local radio station.
  • the speech currents from the repeating coil 89 pass through the contacts of station selecting switch SSW to the primary of repeating coil 5 by which they are impressed on the grid of the amplifier tube 6.
  • the amplified speech waves from the tube 6 are impressed on the second stage.
  • amplifiers 7 and 8 and in the manner that has already been described are caused to modulate the radio frequency wave supplied to the moduof the holes in the flange 93 to lockthe lated waves are then amplified in the power iv-( 06 lea I571, change.
  • the system illustrated in the drawing is adapted for both radio telephone transmission and radio telegraph transmissiom'upon any one of a number of difierent wave lengths.
  • the wave length of the set is changed by means of the wave length switches ⁇ VL, and WL.
  • the switches ⁇ VL and L are connected mechanically either by suitable gearing, sprocket wheels and chains, or cables so that a single control Wheel such as VVL serves to change the antenna tuning, the oscillator tuning and the'tuning of the anti-resonant shunt circuit 38.
  • a single control Wheel such as VVL serves to change the antenna tuning, the oscillator tuning and the'tuning of the anti-resonant shunt circuit 38.
  • mechanical interconnec tion has not been illustrated.
  • the switch Vii is shown as comprising a hand wheel 91, mounted in suitable bearings (not shown) on the framework 92.
  • the wheel 91 carriesa flange 93 with a number of holes at different points along it, corresponding to the various wave length positions.
  • a pin 94 projects from the framework 92 in such position as to extend through one or another wheel 91 against rotation. Then it is desired to change to a new wave length, the wheel 91 is first pulled outward (downward in the drawing) to disengage the pin 94 from the flange 93.
  • the wheel 91 is splined on the shaft 95, so that the wheel may 'be' pulled lengthwise of the shaft without moving the shaft lengthwise.
  • the anti-resonant circuit 38 is as explained above tuned to the radio-frequency and thus offers a substantially infinite impedance to waves of the radio-frequency across the radio-frequency output branch of the modulator M. Since the impedance offered by this circuit rapidly decreases for Power change- T6lephmw-telegraph control.
  • the system shown. in the drawing is adapted both for radio-telephone and radio-telegraph transmission.
  • different; amounts of radio-frequency power are used for the two kinds of. transmission, and, of course, the voice frequency amplifier VA is not required for telegraph transmission.
  • a unitary power control switch PC is provided for shifting quickly from one type of transmission to the other and for effecting the necessary changes in the tube circuits to accommodate the two kinds of transmission. It is found inpractice that different power or different impedance adjustments are desirable for different wave lengths and a further provision is made on the-power control switch for altering the power and impedance relays of the circuit as maybe desired.
  • the power control switch PC is provided with a hand wheel 101 substantially like that of the wave length switch 'VVL and also has the mechanical lock features described in connection with the wheel "VVL lV hen a change is to be made in the adjustment of the power control switch PC, the hand wheel 10! is first withdrawn to enable the wheel to be rotated, and in such withdrawal the lead 31 is broken at contacts 102. This causes relays 13, 21, 22, 23 and 24 all to become deenergized as above described and to disconnect the power sources from all of the tube circuits. As soon as the hand wheel 101 is restored to position to close contacts 102, theserelays again execute the cycle of operations above described to reapply power to the tubes of the system.
  • the central arm 104 of the power control switch moves over two segments TP corresponding to radio-telephone transmission and TG corresponding to radio-telegraph transmission.
  • relay 81 is energized, causing the filaments of the voice amplifier tubes VA to be lighted.
  • the central switch arm 104 is moved off from the segment TP on to the segment TG, thus opening the circuit of relay 81 and removing the filaments of the voice amplifier tubes from circuit.
  • a ,circuit is now established through relay 103 this circuit extending from conductor 17,-1ead 82 (Fig. 3) switch arm 104, segment-ITP, winding of relay 103, lead 105 to conductor 18.
  • the amplitude of the radio-frequency waves impressed on the power amplifier from the modulator M is controlled by taps along the resistance 111, these taps being connected to thepower amplifier input by the switch arm 112, under control of the switch PC.
  • the polarizing potential of the grids of the power amplifier is controlled by switch arm 113, which establishes connection from the grids through the radio-frequency choke 114 and conductor 115 to switch arm 113 and to taps along resistance 116', bridged across the grid polarizing potential leads 73 and 74.
  • the power adjustment for the power amplifier is made under control of switch arm 104 and its cooperating contacts for controlling relays 84, 85, and 86. Depending upon the setting of the switch arm 104, one or another of these three relays is energized to include one or another number of turns of the primary coils 40 in circuit across the power leads 61, 62 and 63, thus varying the step-up voltage ratio of the transformer.
  • relay 15 deenergizes and at its back contact closes a shortcircuit across relay 14 extending from upper door switch contact, winding of relay 14, back contact of relay 15, and then to the upper contact of the door switch again.
  • Relay 14 deenergizes, opening at its rlghthand contact, conductor 79 and causing relays 13, 21, 22, 23 and 24 to deenergize.
  • relay 13 disconnects the relay generator 20 from the i the system is disabled as a. result of any one power and power amplifier panels and relay 22 opens the plate supply circuit of the voice amplifier VA and the oscillator and modulator tubes.
  • relay 41 (Fig. 4) energizes and opens conductor 32. This conductor would also be opened if either overload relay 77 or 78 on the power panel becameenergized, due to an abnormal current being drawn by the power transformer.
  • relay 19- remains energized, due to the locking circuit extending through its left-hand armature. Except for the attendants auxiliary controls 121 and 122, it is therefore impossible to reenergize relay 14, without first opening conductors 17 and 18.
  • This arrangement is desirable in that the attention of the operator is necessary to restart the system when it is automatically shut down by an abnormal and dangerous condition. For example, in the case of a partial obstruction which did not sufiiciently reduce the pressure of the cooling system, to operate the contacts of the gauge 75, .the temperature might rise sufficiently to energize relay 16 and cause the power to be shut down. With the type of control provided by the invention as described above, it is made impossible for'the system to restart in case it merely stands idle until the temperature drops sufliciently to open the circuit of relay 16 again.
  • the circuit of relay 14 as'described also includes a contact of the door switch. It is therefore impossible to start the system or to-appl'y any high voltages thereto, until the door by which rear of the panels are closed, or in case a door is opened while the system is operating and an attendant goes to the rear of the panels, the system will not restar-t by the accidental closing of the door.
  • a restart y takes place immediately after either a wave Y length or a power readjustment of the cir-' cuit, whereas a restart can only be made by the deliberate act of an attendant in case of a number of abnormal conditions.
  • a space discharge device having a cathode adapted to be heated, and an anode, a cathode heating circuit, a space current su ply circuit, a generator having a field an an armature for energizing said space current circuit, circuit closing devices for said circuits, means for closing the field of the space current generator dependent upon the circuit closing device for the space current circuit having been reviously actuated, said means being also ependent for its operation upon the cathode-heatingcircuit having been previously energized.
  • space dischargeelectrodes comprising a cathode to be heated and an anode, energizing circuits therefor, a start key, and automatically operating means for first energizing the cathode in response to the actuation of said key. and for thereafter gradually energizing the anode circuit.
  • a s ace discharge device having a cathode an an'anode, a generator having afield amd an armature for supplying space current to said device, switching means for closing the, armature circuit only when the field energization is substantially zero, and switching means op erating in response to the actuation of said first mentioned switching means for energizing the field.
  • an oscillation generator having a resonant circuit for detel-mining the frequency of the oscillations generated, an antenna circuit, .connections between said generator and said antenna, an anti-resonan circuit in. bridge of said connections, and means for simultaneously changing the constants of the tunedv circuit of said generator, said anti-resonant circuit and said antenna in tune with the generator, and the bridged circuit anti-resonant at the wave length being transmitted.
  • a system-adjusting switch a control gircuit adapted when closed tocause the energization of the tube circuitsi in redetermined sequence and when open to I eenergize the tube circuits, and means .controlled in the initial movement of the adjustin switch for opening said control circuit'an controlled in the final movement of said adjusting switch for closing said control switch.
  • a space a series of control devices for-said energizingcircuits, a control circuit for automatically actuating said control devices in predetermined seque nce, andv a safety circuit actuated in response to abnormal conditions.
  • a space discharge tube energizing circuits therefor control devices for opening and closing sai circuits, a manual control, a control circuit for automatically operating said devices to energize said tube circuits in predetermined: sequence and. to deenergize said tube circuits, said control circuit being a controlled in said manual control, and a safety circuit actuated in response to an abnormaL'condition of said system, including means for causing said control circuit to .deenergize said tube circuits and for rendering said safety circuit powerless to cause reenergiza- I tion of the tube circults.
  • a spacedis charge tube a source of three-phase "alters nating current for supplying space' discharge current thereto, a space' 'discharlge e er foreach phase "for rectifying t ener iz' circuits therefor g y different secondary cirbn the secondary side including. in clrcuit with a said rectifier two' se'con ry coils on different core branches.
  • aradio transmitting system In aradio transmitting system, a plurality of vacuum tubes, energizing circuits.
  • wave-change switches for the system, means for initially. energizing said .tubes,
  • a radio traiismitting system means to transmit radio waves modified in accord ance with telegraph and with. telephone signals alternatively, a switchfor altering the circuits from. one kind of signaling to the other," and means controlled from said Switch for changing the power. output of said system.

Landscapes

  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Transmitters (AREA)
  • Arrangements For Transmission Of Measured Signals (AREA)
US731906A 1924-08-14 1924-08-14 Radiotransmitter Expired - Lifetime US1565505A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US731906A US1565505A (en) 1924-08-14 1924-08-14 Radiotransmitter

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US731906A US1565505A (en) 1924-08-14 1924-08-14 Radiotransmitter
GB8827/25A GB247774A (en) 1925-04-02 1925-04-02 Improvements in vacuum tube systems for the transmission of high frequency signals

Publications (1)

Publication Number Publication Date
US1565505A true US1565505A (en) 1925-12-15

Family

ID=9859973

Family Applications (1)

Application Number Title Priority Date Filing Date
US731906A Expired - Lifetime US1565505A (en) 1924-08-14 1924-08-14 Radiotransmitter

Country Status (5)

Country Link
US (1) US1565505A (enrdf_load_stackoverflow)
DE (1) DE547268C (enrdf_load_stackoverflow)
FR (1) FR598212A (enrdf_load_stackoverflow)
GB (1) GB247774A (enrdf_load_stackoverflow)
NL (1) NL17963C (enrdf_load_stackoverflow)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2472157A (en) * 1945-11-01 1949-06-07 Wiegand Co Edwin L Control system
US2538217A (en) * 1945-09-29 1951-01-16 Kelley Koett Mfg Company X-ray apparatus
US3718862A (en) * 1969-06-30 1973-02-27 Sound Syst Int Inc Wireless microphone and adapter kit

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
NL295488A (enrdf_load_stackoverflow) * 1962-07-19

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2538217A (en) * 1945-09-29 1951-01-16 Kelley Koett Mfg Company X-ray apparatus
US2472157A (en) * 1945-11-01 1949-06-07 Wiegand Co Edwin L Control system
US3718862A (en) * 1969-06-30 1973-02-27 Sound Syst Int Inc Wireless microphone and adapter kit

Also Published As

Publication number Publication date
FR598212A (fr) 1925-12-09
NL17963C (enrdf_load_stackoverflow) 1928-04-15
DE547268C (de) 1932-03-23
GB247774A (en) 1926-02-25

Similar Documents

Publication Publication Date Title
US2304377A (en) Automatic frequency control system
US2066522A (en) Protective system and method
US1565505A (en) Radiotransmitter
US2385673A (en) Carrier current system
US2084899A (en) System of electrical distribution
US2192061A (en) Carrier current system
US2208183A (en) Electric power transmission system
US1848824A (en) System of distribution
US2274271A (en) Transmitting system
US1796071A (en) High-frequency repeater
US2342787A (en) Carrier current transmission system
US1797976A (en) Fault-responsive apparatus
US2540638A (en) Automatic step control of current
US2015591A (en) Control circuit
US2246307A (en) Signal transmission line
US2287504A (en) Protective apparatus
US1473433A (en) Carrier-wave transmission system
US1825303A (en) Radio transmitting system
US1634800A (en) Rectifying and modulating system
US2792483A (en) Generator arc protection circuit
US1480722A (en) Means for and method of eliminating harmonic disturbances
US1485156A (en) System of distribution
US2018225A (en) Network system for distribution
US2615984A (en) Single-tube frequency-modulated oscillator
US1728403A (en) Alternator-field-control system