US2137278A - Amplifier system - Google Patents
Amplifier system Download PDFInfo
- Publication number
- US2137278A US2137278A US42817A US4281735A US2137278A US 2137278 A US2137278 A US 2137278A US 42817 A US42817 A US 42817A US 4281735 A US4281735 A US 4281735A US 2137278 A US2137278 A US 2137278A
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- US
- United States
- Prior art keywords
- tube
- amplifier
- tubes
- stage
- shielding means
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- 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.)
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N5/00—Details of television systems
- H04N5/30—Transforming light or analogous information into electric information
Definitions
- the present. invention relates to amplifiersand particularly to amplifiers which are useful in connection with television and picture transmission systems, although the use is in no sense limited specifically to such types of systems.
- the D. C. component of the picture or subject may be added to the picture. This is. preferably accomplished at the receiving end of the system and the compensation may be under the. controlof the synchronizing impulses or some other portion of the signal.
- Another advantage to be obtained through the use of a direct current amplifier system is that a small change inthe direct current or voltage at the input terminals of the amplifier may be represented by a large change in direct current or voltage at the output terminals without distortion.
- light representing difierent successive elemental areas of the subject I is caused to fall upon a photoelectric cell or other suitable light translating element 3 by scanning the i1- luminated subject, for example, by means of a rotary scanning disk or other equivalent element 5 such as a cathode ray tube, oscillating mirror or the like.
- the subject I for example, may be illuminated from a source I by way of an optical system 9 and the light from the subject, in turn, is directed by way of a second optical system 13, the light passing beyond the scanning element is caused to fall upon the light sensitive photo- 50 electric cell 3.
- the photoelectric cell 3 is connectedinserieswith abattery I51 and resistor I!
- the output circuit. of the tube l9 includes the anode electrode of the tube, the resistor 23 andthe plate supply source 25. Across opposite terminals of the resistor 23 through which varyingvoltage drops take place 15; in accordance with.
- the current flowing through the tube l9 (as determined by the potential of that. terminal offthe, resistor l1 connected adjacent the control grid of the. tube, I9), is, connected' the inputcircuiti of the secondstage of the amplifier which comprises'the tube 21.
- the tube 21 may consist, like the tube I9, of" three ormore, electrodes of which one is an electron emitter. and another is an anode.
- the tube 21 includes in its output circuit the tube anode, the resistor 29 and the source of abode voltage 3
- the con- 40 .trol electrode of the tube I9 is biased by the battery 2
- An outside shield box 31 is also provided for housing each of the initial shield boxes in order to provide full and complete shielding for all 0 stages of the amplifier.
- the outer shield box 31 is preferably grounded at 39.
- a multi-stage amplifier system comprising a plurality of cascaded thermionic tubes, a source of anode voltage for each of said tubes, means for controlling the output current from the first of said tubes in accordance with a variable quantity so as to control thereby the current flowing through subsequent tubes, means for biasing the second tube of the series from the source of anode voltage for said tube, separate electrostatic shielding means surrounding each of said tubes, a con' nection from the positive terminal of the anode voltage source for each tube to said shielding means, and a second shielding means surrounding all of said tubes and the individual shields therefor and insulated from the first named shielding means.
- a multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light 1 modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate'electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, and a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential.
- a multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, thereby placing said shields at a potential relative to the cathode of at least one of the tubes which is progressively higher from the first tube, and a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential.
- a multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, thereby placing said shields at a potential relative to the cathode of at least one of the tubes which is progressively higher from the first tube, a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential, and shielding means separating each of the separate electrostatic shielding means enclosing each stage of the amplifier and insulated therefrom.
Description
9 R. H. GEORGE ET AL AMPLIFIER SYSTEM Filed Sept. 30', 1935 INVENTORS T ORNEY Patented Nov. 22, 1938 UNITED STATES PATENT OFFICE AMPLIFIER SYSTEM.
Application September 30,.1935', S'eriallN o. 42,817
4 Claims. (01; 250-415) The present. invention relates to amplifiersand particularly to amplifiers which are useful in connection with television and picture transmission systems, although the use is in no sense limited specifically to such types of systems.
In television systems it has been found frequently to be desirable to resort to the so-called D. C. amplifier type of system where itis desired tohold the picture level or background at any particular point. When using a D. C. amplifier in such systems it is possible to transmit in correct relationship to the entire picture continued along dark or light portions of the subject, whereas in the so-called A. C. amplifier type of system it is necessary to provide special ways.
and meanswhereby the D. C. component of the picture or subject may be added to the picture. This is. preferably accomplished at the receiving end of the system and the compensation may be under the. controlof the synchronizing impulses or some other portion of the signal.
Another advantage to be obtained through the use of a direct current amplifier system is that a small change inthe direct current or voltage at the input terminals of the amplifier may be represented by a large change in direct current or voltage at the output terminals without distortion.
The above and other objects are those sought to be attained by the present invention, although we do not in any way limit ourselves to any or all of the foregoing objects or advantages of such a system as is disclosed herein.
For the purpose of illustrating our invention, we have shown by diagrammatic sketch embodying the single figure of the drawing one form which the said invention may assume and have confined the illustration only to the first two stages of an amplifier of the character above described.
If reference is now made to the drawing, it will be seen that light representing difierent successive elemental areas of the subject I is caused to fall upon a photoelectric cell or other suitable light translating element 3 by scanning the i1- luminated subject, for example, by means of a rotary scanning disk or other equivalent element 5 such as a cathode ray tube, oscillating mirror or the like. The subject I, for example, may be illuminated from a source I by way of an optical system 9 and the light from the subject, in turn, is directed by way of a second optical system 13, the light passing beyond the scanning element is caused to fall upon the light sensitive photo- 50 electric cell 3. The photoelectric cell 3 is connectedinserieswith abattery I51 and resistor I! so that duetovarying conditions of light falling upon the photocelLvarying voltage drops take, place in, the. resistor l1. Connected across the terminals. of the. resistor element I1. is the first. stage of, the amplifier system. This first stage of the amplifier islso connected that the input circuit comprising thegrid-cathode circuit of the tube l9, connectsto. opposite terminals-of the resistor IT and'the. controlgrid'is appropriately biased by 10; way of. a biasing battery 2|. The output circuit. of the tube l9 includes the anode electrode of the tube, the resistor 23 andthe plate supply source 25. Across opposite terminals of the resistor 23 through which varyingvoltage drops take place 15; in accordance with. the current flowing through the tube l9 (as determined by the potential of that. terminal offthe, resistor l1 connected adjacent the control grid of the. tube, I9), is, connected' the inputcircuiti of the secondstage of the amplifier which comprises'the tube 21. The tube 21., for example, may consist, like the tube I9, of" three ormore, electrodes of which one is an electron emitter. and another is an anode.
While we have shown in the accompanying illustration tubes of the triode type, it is to be understood that we may also utilize tubes of the so-called screen grid, pentode, hexode, and other types, or we may use any desired multi-purpose tubes provided other characteristics of the in vention remain unchanged.
The tube 21 includes in its output circuit the tube anode, the resistor 29 and the source of abode voltage 3| similarly to the tube l9. In contrast to the arrangement by which the con- 40 .trol electrode of the tube I9 is biased by the battery 2|, we have provided an arrangement wherein the tube 21 is appropriately biased by means of the plate battery of the tube I9 of which the positive terminal is connected to an 45 intermediate point 33 on the source of plate potential 3! for the tube 21. All succeeding stages (not shown) of the amplifier are preferably biased in the same manner as that provided for the second stage. 0
In order to shield different sections of the amplifier with respect to each other, there are provided separate shielding boxes 35 for each stage and the positive terminal of the plate voltage 55 supply for each of the tubes l9 and 2?, as shown, is connected to one of the shielding boxes 35. An outside shield box 31 is also provided for housing each of the initial shield boxes in order to provide full and complete shielding for all 0 stages of the amplifier. The outer shield box 31 is preferably grounded at 39.
With the arrangement hereinabove shown, there results an amplifier which is of extreme stability in operation. All succeeding stages of the amplifier are connected to the output terminals 4| the terminals 41 may connect directly to the modulator and thence to the transmitter.
Having now described the invention, what is claimed and desired to secure by Letters Patent is the following:
1. A multi-stage amplifier system comprising a plurality of cascaded thermionic tubes, a source of anode voltage for each of said tubes, means for controlling the output current from the first of said tubes in accordance with a variable quantity so as to control thereby the current flowing through subsequent tubes, means for biasing the second tube of the series from the source of anode voltage for said tube, separate electrostatic shielding means surrounding each of said tubes, a con' nection from the positive terminal of the anode voltage source for each tube to said shielding means, and a second shielding means surrounding all of said tubes and the individual shields therefor and insulated from the first named shielding means.
2. A multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light 1 modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate'electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, and a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential.
3. In a multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, thereby placing said shields at a potential relative to the cathode of at least one of the tubes which is progressively higher from the first tube, and a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential.
' 4. In a multi-stage amplifier comprising a plurality of directly connected thermionic tubes, means for controlling the output current from the first thermionic tube in accordance with light modulations, means for controlling the output of the following tubes in the system in accordance with the output of the first tube of the series, means for biasing each tube of the series from the source of anode voltage for the selected tube of the series, separate electrostatic shielding means enclosing each stage of the amplifier and joined to the positive terminal of the anode voltage source for said stage, thereby placing said shields at a potential relative to the cathode of at least one of the tubes which is progressively higher from the first tube, a second shielding means surrounding the entire amplifier and insulated from each of the individual shields, said second shielding means being maintained at ground potential, and shielding means separating each of the separate electrostatic shielding means enclosing each stage of the amplifier and insulated therefrom.
ROSCOE H. GEORGE. HOWARD J. HEIM.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US42817A US2137278A (en) | 1935-09-30 | 1935-09-30 | Amplifier system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US42817A US2137278A (en) | 1935-09-30 | 1935-09-30 | Amplifier system |
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US2137278A true US2137278A (en) | 1938-11-22 |
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US42817A Expired - Lifetime US2137278A (en) | 1935-09-30 | 1935-09-30 | Amplifier system |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2434223A (en) * | 1944-03-15 | 1948-01-06 | American Cyanamid Co | High gain amplifier |
US2548770A (en) * | 1945-05-30 | 1951-04-10 | John B Caraway | Protective arrangement for the neutralization circuits of vacuum tubes |
US2591837A (en) * | 1946-03-27 | 1952-04-08 | Nasa | Method and apparatus for signaling employing polarized lights |
US2609442A (en) * | 1948-12-29 | 1952-09-02 | Faximile Inc | Recorder amplifier with grounded positive and balanced input circuit |
US2864278A (en) * | 1955-03-07 | 1958-12-16 | Phillips Petroleum Co | Refractometer |
US3084321A (en) * | 1958-09-29 | 1963-04-02 | Beckman Instruments Inc | Method of and apparatus for transferring analog signal voltages |
US3196364A (en) * | 1961-05-16 | 1965-07-20 | Honeywell Inc | Shielded differential amplifier |
US3896425A (en) * | 1973-10-16 | 1975-07-22 | Tyco Laboratories Inc | Proximity detector |
-
1935
- 1935-09-30 US US42817A patent/US2137278A/en not_active Expired - Lifetime
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2434223A (en) * | 1944-03-15 | 1948-01-06 | American Cyanamid Co | High gain amplifier |
US2548770A (en) * | 1945-05-30 | 1951-04-10 | John B Caraway | Protective arrangement for the neutralization circuits of vacuum tubes |
US2591837A (en) * | 1946-03-27 | 1952-04-08 | Nasa | Method and apparatus for signaling employing polarized lights |
US2609442A (en) * | 1948-12-29 | 1952-09-02 | Faximile Inc | Recorder amplifier with grounded positive and balanced input circuit |
US2864278A (en) * | 1955-03-07 | 1958-12-16 | Phillips Petroleum Co | Refractometer |
US3084321A (en) * | 1958-09-29 | 1963-04-02 | Beckman Instruments Inc | Method of and apparatus for transferring analog signal voltages |
US3196364A (en) * | 1961-05-16 | 1965-07-20 | Honeywell Inc | Shielded differential amplifier |
US3896425A (en) * | 1973-10-16 | 1975-07-22 | Tyco Laboratories Inc | Proximity detector |
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