US2072953A - Cascaded electron tube system - Google Patents
Cascaded electron tube system Download PDFInfo
- Publication number
- US2072953A US2072953A US598984A US59898432A US2072953A US 2072953 A US2072953 A US 2072953A US 598984 A US598984 A US 598984A US 59898432 A US59898432 A US 59898432A US 2072953 A US2072953 A US 2072953A
- Authority
- US
- United States
- Prior art keywords
- tube
- current
- potential
- resistance
- output
- 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
Links
- 230000000694 effects Effects 0.000 description 9
- 230000008878 coupling Effects 0.000 description 3
- 238000010168 coupling process Methods 0.000 description 3
- 238000005859 coupling reaction Methods 0.000 description 3
- 238000004804 winding Methods 0.000 description 3
- 238000006073 displacement reaction Methods 0.000 description 2
- 238000005513 bias potential Methods 0.000 description 1
- 238000013016 damping Methods 0.000 description 1
- 230000003247 decreasing effect Effects 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 238000010438 heat treatment Methods 0.000 description 1
- 239000003381 stabilizer Substances 0.000 description 1
Images
Classifications
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F3/00—Amplifiers with only discharge tubes or only semiconductor devices as amplifying elements
- H03F3/34—DC amplifiers in which all stages are DC-coupled
- H03F3/36—DC amplifiers in which all stages are DC-coupled with tubes only
Definitions
- My present invention relates broadly to cascadecl electron tube systems, and more particularly to such systems adapted to repeat, amplify, detect and translate alternating electrical currents.
- An object of my said invention is efficient and faithful functioning of the elements of the systems utilized by me towards accomplishing novel results.
- a particular object is to utilize efiects produced from the signal alternating electrical currents after introduction of them into the system to contribute beneficially to the desired functioning of the system.
- Another object is to rectify 'modulated high frequency carrier ourrents for usual detection purposes, and to additionally utilize the direct current component of the rectified currents for developing a useable biasing potential for effecting in a helpful way the operation of succeeding elements in the system.
- Fig. 1 diagrammatically illustrates the features of my invention usefully embodied in a radio receiver.
- Fig. 2 is the system of Fig. 1 modified to include a special control feature.
- the element I is an antenna coupled to a screen-grid type of electron tube .ATl through a tunable circuit 2, the output of which tube includes a primary coil 3 coupled to a second tunable circuit 4, thus constituting a tunable radio frequency amplifier of form usual in the radio receiving art.
- I show connected across tunable circuit 4 an alternating current rectifying device DT of any suitable form, a. two-electrode tube having heated cathode and associated anode being illustrated.
- a resistance R1 In series with the rectifier I insert a resistance R1, and across this resistance I connect the input electrodes of a multiple electrode tube ATz, shown for example as a usual three electrode tube, preferably connected and energized to amplify.
- This arrangement provides for the responsively variable direct current component of 20 the output current of tube A'I'z developing in coupling resistance R2 a responsively varying grid biasing potential for output tube ATs'having its input electrodes connected thereacross, which effect thereby reaches the output circuit 25 of this last tube in considerably amplified form, but in response accord with the intensity characteristics of the incoming signal currents.
- the average plate cur- 30 rent of the output tube does not remain at the mid-point of the plate current characteristic curve, a. condition striven for in prior electron tube amplifier systems, but drifts away from this point in proportion to the strength of the incom- 35 ing signals.
- Fig. 1 The system of Fig. 1 is shown energi' ed in conventional manner from a source of alternating current connected across primary P of transformer T1.
- a rectifier R is supplied with alternating current by secondary winding $1, the rectified current being filtered by the system comprising inductance L and condensers C1 and 02..
- Condenser C3 is a signal current by-pass across the output circuit of output tube ATs.
- T3 is a transformer for transferring signal current to a translating device LS.
- R3 is a potential reducing resistance in series with coupling resistance R2 and the space current path of tube ATz.
- Condenser C4 is a signal current by-pass.
- R4 is a potential developing resistance for the output circuit of tube ATz.
- R5 and Re are potential reducing resistances for the plate and screen-grid electrodes of tube AT1
- condensers C5 and C7 are the usual filter and signal current by-pass condensers.
- Resistance R7 shunted by condenser C6 is the usual arrangement for developing a biasing potential for tube ATi.
- the cathodes of tubes ATi, DT, and AT: are shown as of the indirectly heated type, and theheaters of these tubes may be heated by current from any suitable source, such as secondary Winding S3 on transformer T1.
- the cathode of tube AT3 is shown to be of the filament type, and may be heated by current from any suitable source, such as secondary winding S2.
- the filament of rectifier tube R is shown supplied with heating current from secondary S4.
- Fig. 2 I use a tube at ATz of the screengrid type having an electrode SG electrostatically shielding the anode from the control grid. I positively energize the screen-grid by a chosen connection to a potential point in resistance R4, the connection being by-passed asis usual by a condenser Cs. Since resistance R4 is in series with the discharge path of output tube A'I's, its degree of developed unidirectional potential therein depends upon the degree of direct current component of the current in the discharge path, as does the potential established on screengrid electrode SG. The resulting variation of potential on screen-grid SG produces an effect opposing variation in the output current. of tube ATa, or tending to limitedly stabilize the effect. The arrangement of Fig. 2 provides for limiting the effect in the output circuit in a desired degree, thus facilitating designing a system properly coordinated throughout.
- a screen-grid tube means including a signal current rectifier determining the control grid biasing potential of said tube as a function of the intensity of said signal current, .and means for impressing on the screen-grid of said tube amplified reflections of variations of said control grid biasing potentials.
- a tunable input circuit for the signal currents a current rectifier and resistance series related connected across said tunable circuit, a screen grid tube having its control electrode and cathode conductively connected across difference of potential points in said resistance, a second resistance in the anode-cathode circuit of said tube, a multiple electrode tube having its control electrode and cathode connected across difference of potential points in said second resistance, a third resistance through which the anode-cathode current of said second tube flows, and a connection between the screen-grid of said first tube and a selected potential point in said third resistance.
- a tunable signal circuit a two-electrode tube having cathode and anode elements and an effective resistance inseries therewith connected across said tunable circuit, whereby unidirectional potentials are effectively developed in said resistance by the currents from said circuit rectified by said tube, a multiple electrode tube having its input electrodes so connected to said resistance that the resulting unidirectional potential impressed on the control electrode of said second tube constitutes an eifective operating biasing potential on said control electrode whose value is a function of said signal currents, a third tube for utilizing the resulting output currents of said second tube, and a direct current pathbetween the third tube space current path and a cold electrode of the second-tube other than the control electrode and plate thereof.
Landscapes
- Engineering & Computer Science (AREA)
- Power Engineering (AREA)
- Amplifiers (AREA)
Description
March 9, 1937. 1 KELLEY 4 2,072,953
CASCADED ELECTRON TUBE SYSTEM Filed March 15, 1932 2 Sheets-Sheet l INVENTOR ATTORNEY March 9, 1937.
G.J.KELLEY CASCADED ELECTRON TUBE SYSTEM Filed March 15, 1932 2 Shee'ts-Shet 2 INVENTOR 627w?" J/[eld y ATTORNE Patented Mar. 9, 1937 UNITED STATES CASCADED ELECTRON TUBE SYSTEM Gerard J. Kelley, New York, N. Y., assignor, by mesne assignments, to Radio Corporation of America, New York, N. Y., a corporation of Delaware Application March 15, 1932, Serial No. 598,984
4 Claims.
My present invention relates broadly to cascadecl electron tube systems, and more particularly to such systems adapted to repeat, amplify, detect and translate alternating electrical currents.
An object of my said invention is efficient and faithful functioning of the elements of the systems utilized by me towards accomplishing novel results. A particular object is to utilize efiects produced from the signal alternating electrical currents after introduction of them into the system to contribute beneficially to the desired functioning of the system. Another object is to rectify 'modulated high frequency carrier ourrents for usual detection purposes, and to additionally utilize the direct current component of the rectified currents for developing a useable biasing potential for effecting in a helpful way the operation of succeeding elements in the system.
Further objects and the features of my said invention will be appreciated from the following description based upon the two figures of the accompanying drawings in which like reference characters represent like parts so far as practicable.
Fig. 1 diagrammatically illustrates the features of my invention usefully embodied in a radio receiver.
Fig. 2 is the system of Fig. 1 modified to include a special control feature.
Referring to Fig. 1, the element I is an antenna coupled to a screen-grid type of electron tube .ATl through a tunable circuit 2, the output of which tube includes a primary coil 3 coupled to a second tunable circuit 4, thus constituting a tunable radio frequency amplifier of form usual in the radio receiving art.
I show connected across tunable circuit 4 an alternating current rectifying device DT of any suitable form, a. two-electrode tube having heated cathode and associated anode being illustrated. In series with the rectifier I insert a resistance R1, and across this resistance I connect the input electrodes of a multiple electrode tube ATz, shown for example as a usual three electrode tube, preferably connected and energized to amplify.
It is thus seen that alternating current impressed on series connected rectifier DT and resistance R1 will develop across resistance R1 a rectified or unidirectional potential which is impressed as a biasing potential on the grid of tube ATz, the proportions of which potential depend upon the intensity cfthe impressed alternating current. This biasing results in direct currentcomponent of the output current of tube AT: varying responsively with the bias potential established on the grid of tube ATz, and therefore with the intensity of the bias establishing in- 5 coming alternating current.
It is possible to amplifiedly extend this effect to make practical use of it. In my co-pending application Serial Number 451,562, filed May 12, 1930, Patent No. 1,954,779, April 10, 1934, I show 10 various examples of so-called direct-coupled cascaded electron tube systems capable of relaying and amplifying direct current effects. I employ a like arrangement in Fig. 1 in connecting the grid of the output tube A'I's directly to the plate of tube AT2, and coupling the tubes for energy transfer therebetween by a high resistance R2 as explained in my said co -pending application. This arrangement provides for the responsively variable direct current component of 20 the output current of tube A'I'z developing in coupling resistance R2 a responsively varying grid biasing potential for output tube ATs'having its input electrodes connected thereacross, which effect thereby reaches the output circuit 25 of this last tube in considerably amplified form, but in response accord with the intensity characteristics of the incoming signal currents. In other words, when the system is operating to receive incoming signals the average plate cur- 30 rent of the output tube does not remain at the mid-point of the plate current characteristic curve, a. condition striven for in prior electron tube amplifier systems, but drifts away from this point in proportion to the strength of the incom- 35 ing signals.
In prior consideration of so-called directcoupled electron tube systems, such as disclosed in copending application of S. Y. 'White, Serial Number 381,754, filed July 29, 1929, Patent No. 40 2,082,193, February 25, 1936, and my aforesaid co-pending application, it was considered undesirable to permit the rectification of the incoming signal current to sustainedly displace the direct current component of the plate current of 45 the output circuit from the mid-point of the characteristic curve for fear of introducing early distortion in the power output ability of the output tube, so that it has been the practice to use so-called stabilizers to correctively over- 9 come the effect.
I have now found that permitting the in-accord responsive displacement of the average of the space current of the output tube is not undesirable, but to the contrary is helpful and ben- 55 eficial to a system such as disclosed in Fig. 1. Instead of the undistorted power output ability of the output tube being decreased, as was previously contemplated, I find that permitting the displacement to take place increases the undistorted power output ability, I having accomplished as much as a 100 percent increase over normal in usual commercial types of amplifier output tubes, and with decidedly pleasing tonal effects. Since I have been unable to arrive at any satisfactory explanation of the physics involved in bringing about the results I have produced, I attempt no explanation in connection with this description.
When I use a high frequency tunable circuit for the input circuit A in advance of an electron emitting diode for the rectifier DT as shown, I prefer to connect the diode anode to the grid 'of the succeeding tube AT2, as in this way I lessen the damping effect on the tunable circuit of grid current fiow from tube A'Iz.
The system of Fig. 1 is shown energi' ed in conventional manner from a source of alternating current connected across primary P of transformer T1. A rectifier R is supplied with alternating current by secondary winding $1, the rectified current being filtered by the system comprising inductance L and condensers C1 and 02.. Condenser C3 is a signal current by-pass across the output circuit of output tube ATs. T3 is a transformer for transferring signal current to a translating device LS. R3 is a potential reducing resistance in series with coupling resistance R2 and the space current path of tube ATz. Condenser C4 is a signal current by-pass. R4 is a potential developing resistance for the output circuit of tube ATz. R5 and Re are potential reducing resistances for the plate and screen-grid electrodes of tube AT1, and condensers C5 and C7 are the usual filter and signal current by-pass condensers. Resistance R7 shunted by condenser C6 is the usual arrangement for developing a biasing potential for tube ATi. The cathodes of tubes ATi, DT, and AT: are shown as of the indirectly heated type, and theheaters of these tubes may be heated by current from any suitable source, such as secondary Winding S3 on transformer T1. The cathode of tube AT3 is shown to be of the filament type, and may be heated by current from any suitable source, such as secondary winding S2. The filament of rectifier tube R is shown supplied with heating current from secondary S4.
In Fig. 2 I use a tube at ATz of the screengrid type having an electrode SG electrostatically shielding the anode from the control grid. I positively energize the screen-grid by a chosen connection to a potential point in resistance R4, the connection being by-passed asis usual by a condenser Cs. Since resistance R4 is in series with the discharge path of output tube A'I's, its degree of developed unidirectional potential therein depends upon the degree of direct current component of the current in the discharge path, as does the potential established on screengrid electrode SG. The resulting variation of potential on screen-grid SG produces an effect opposing variation in the output current. of tube ATa, or tending to limitedly stabilize the effect. The arrangement of Fig. 2 provides for limiting the effect in the output circuit in a desired degree, thus facilitating designing a system properly coordinated throughout.
While I have described my invention around radio receiving systems, no limitations are intended thereby, the invention being of broad scope as set forth in the appended claims.
Having fully described my invention, I claim:
1. In an electrical signal current transmitting system, a screen-grid tube, means including a signal current rectifier determining the control grid biasing potential of said tube as a function of the intensity of said signal current, .and means for impressing on the screen-grid of said tube amplified reflections of variations of said control grid biasing potentials.
2. In an electrical signal current transmitting system, a tunable input circuit for the signal currents, a current rectifier and resistance series related connected across said tunable circuit, a screen grid tube having its control electrode and cathode conductively connected across difference of potential points in said resistance, a second resistance in the anode-cathode circuit of said tube, a multiple electrode tube having its control electrode and cathode connected across difference of potential points in said second resistance, a third resistance through which the anode-cathode current of said second tube flows, and a connection between the screen-grid of said first tube and a selected potential point in said third resistance.
3. In an electrical system for transmitting alternating signal currents, means for rectifying said currents, means in series with said rectifying means for effectively developing unidirectional potential from the rectified component of said currents, a multiple electrode tube having its input electrodes so connected to said unidirectional potential developing means that the resulting unidirectional potential impressed on the control electrode of said tube constitutes an effective operating biasing potential on said control electrode whose value is a function of the intensity of said signal currents, and means, in-
eluding a second tube utilizing the resulting output currents of said tube, for determining the potential of a second electrode of said first tube.
4. In an electrical signal current transmitting system, the combination of a tunable signal circuit, a two-electrode tube having cathode and anode elements and an effective resistance inseries therewith connected across said tunable circuit, whereby unidirectional potentials are effectively developed in said resistance by the currents from said circuit rectified by said tube, a multiple electrode tube having its input electrodes so connected to said resistance that the resulting unidirectional potential impressed on the control electrode of said second tube constitutes an eifective operating biasing potential on said control electrode whose value is a function of said signal currents, a third tube for utilizing the resulting output currents of said second tube, and a direct current pathbetween the third tube space current path and a cold electrode of the second-tube other than the control electrode and plate thereof.
GERARD J. KELLEY.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US598984A US2072953A (en) | 1932-03-15 | 1932-03-15 | Cascaded electron tube system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US598984A US2072953A (en) | 1932-03-15 | 1932-03-15 | Cascaded electron tube system |
Publications (1)
Publication Number | Publication Date |
---|---|
US2072953A true US2072953A (en) | 1937-03-09 |
Family
ID=24397721
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US598984A Expired - Lifetime US2072953A (en) | 1932-03-15 | 1932-03-15 | Cascaded electron tube system |
Country Status (1)
Country | Link |
---|---|
US (1) | US2072953A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2618707A (en) * | 1946-11-01 | 1952-11-18 | Raytheon Mfg Co | Combination radio receiver and hearing aid |
US2661419A (en) * | 1949-04-18 | 1953-12-01 | Marcel Wallace | Wide band spectrum analyzer |
-
1932
- 1932-03-15 US US598984A patent/US2072953A/en not_active Expired - Lifetime
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2618707A (en) * | 1946-11-01 | 1952-11-18 | Raytheon Mfg Co | Combination radio receiver and hearing aid |
US2661419A (en) * | 1949-04-18 | 1953-12-01 | Marcel Wallace | Wide band spectrum analyzer |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US2346020A (en) | Modulation amplifier and modulator | |
US2247324A (en) | Noise-limiting circuits for carrier wave communication systems | |
US2072953A (en) | Cascaded electron tube system | |
US2346545A (en) | Electron discharge device circuit | |
US2485731A (en) | Wave-signal amplitude-limiting system | |
US2253450A (en) | Automatic volume control system | |
US2237409A (en) | Automatic volume control circuit | |
US2258877A (en) | Electrical circuit damping | |
US2051364A (en) | Automatic sensitivity control circuit | |
US2203485A (en) | Voltage double circuit | |
US2093565A (en) | Automatic gain control circuit | |
US2088230A (en) | Automatic volume control circuit | |
US2031238A (en) | Automatic volume control arrangement | |
US1927560A (en) | Electron tube system | |
US2026944A (en) | Means for receiving and amplifying electric signals | |
US2237421A (en) | Automatic volume control | |
US2107409A (en) | Automatic volume control circuits | |
US2196248A (en) | Combined amplifier-rectifier circuits | |
US2229674A (en) | Rectifying and amplifying circuits | |
US2702837A (en) | Multistage broad band signaltranslating system | |
USRE22537E (en) | Automatic volume control circuits | |
US2058432A (en) | System for detecting and amplifying modulated electrical variations | |
US2233769A (en) | Low frequency modulation expander | |
USRE19857E (en) | Carrier wave receiver | |
US2003110A (en) | Radio receiving system |