US2438586A - Color analyzing circuit - Google Patents

Color analyzing circuit Download PDF

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US2438586A
US2438586A US617857A US61785745A US2438586A US 2438586 A US2438586 A US 2438586A US 617857 A US617857 A US 617857A US 61785745 A US61785745 A US 61785745A US 2438586 A US2438586 A US 2438586A
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terminal
electrons
primary electrons
electrode
proportional
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US617857A
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George C Sziklai
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J40/00Photoelectric discharge tubes not involving the ionisation of a gas
    • H01J40/02Details
    • H01J40/14Circuit arrangements not adapted to a particular application of the tube and not otherwise provided for

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  • This invention relates to color analyzing devices which are utilized to determine hue or color, and has for its principal object the provisionof an improved color analyzer and method of operation which involve less complication than previous devices of this character.
  • this improved color analyzer is based on the fact that the energy of an electron emitted from a photoelectric surface, and hence its velocity, is dependent on the frequency of the light applied to the photoelectric surface.
  • the electrons emitted from a photoelectric surface are affected by the characteristics of the light applied to such surface.
  • the number of emitted electrons increases as the intensity of the light is increased and the energy and velocity of the emitted electrons increase as the frequency of the applied light is increased from the infra-red to the ultra-violet end of the spectrum.
  • the hue or color of light is determined by its frequency
  • the electro velocity is proportional to the frequency of the light proutilized to determine the color of the light by" which the primary electrons are released from the photoelectric surface.
  • Important objects of the invention are the provision of a color analyzer which functions to in dicate or determine'color in response to the frequency of the applied light, and the provision of means whereby the output of an electron multiplier may be rendered independent of the intensity electron.
  • the device of Fig. 1 includes an electron-multiplier. A, an amplifier B, and a meter C which respondsto the current of the secondary electrons of the device A and is calibrated in terms of color.
  • the electrode E is of the type producing high secondary electron emission.
  • the number of secondary electrons that leave it in response to each primary electron varies with the velocity of the. primary electron as indicated-by the curve of Fig. "2. If the potential applied to the electrode E is maintained at a value low enough-to keep the velocity of the secondary electrons below its maximum value, the current between the electrodes E and F is proportional (1) to the speed of the primary electrons striking theelectrode E and (2) to the number of primary electrons.
  • the device Since the device is required to respond only to the velocity of the primary electrons, some means must'be provided for neutralizing the effect otherwise produced by variationin the intensity of the light applied to the electrode D.
  • This undesired eifect is neutralized or compensated by means of a direct current amplifier bridge circuit.
  • the different arms of this bridge circuit consist of (1) the 'plate circuit of the direct current amplifier B, (2) opposite sections of a resistor R2 and (3) the electrodes E and F of the device A. Connected across thediagonal of thebridge circuit are the meter C and a battery H polarized as indicated.
  • the grid circuit of the amplifier B includes a resistor R1 and a battery G polarized as indicated. The potential applied to thegrid of the amplifier B is determined by the resultant difference between the voltage of the battery G and the voltage develaesase rectly proportional to the current between the.
  • ondary electrons are applied to an output e1ec-.
  • trode a pair of impedance elements having a terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, means for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said primary electrons, and means connected to said terminal for producing an indication proportional in value to said component current which is proportional to the speed of said primary electrons.
  • put electrode a pair of impedance devices having a terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, and means including said emissive and output electrodes for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said secondary electrons.
  • said emissive and output connected between said terminal and a terminal common to said emissive electrode and the cathode of said electron discharge device for indicating a quantity proportional in value to the speed of said primary electrons.

Description

March 30, 1948. e. c. SZlKLAl 2,438,586
COLOR ANALYZING CIRCUIT Filed Sept. 2l, 1945 INVENTOR George .flX/Zii ATTORN EY Patented Mar. 30, 1948 George C. Sziklai, Princeton,
N. J., assignor to Radio Corporation of America, a corporation of Delaware Application September 21, 1945, Serial No. 617,857
9 Claims. 1
This invention relates to color analyzing devices which are utilized to determine hue or color, and has for its principal object the provisionof an improved color analyzer and method of operation which involve less complication than previous devices of this character.
The operation of this improved color analyzer is based on the fact that the energy of an electron emitted from a photoelectric surface, and hence its velocity, is dependent on the frequency of the light applied to the photoelectric surface.
It is well known that the electrons emitted from a photoelectric surface are affected by the characteristics of the light applied to such surface. Thus, the number of emitted electrons increases as the intensity of the light is increased and the energy and velocity of the emitted electrons increase as the frequency of the applied light is increased from the infra-red to the ultra-violet end of the spectrum. Otherwise stated, the hue or color of light is determined by its frequency, and
the more nearly the color approaches the ultraviolet end of the spectrum the greater the energy of the electrons which it causes to be emitted from a photoelectric surface.
The relation between light frequencies (hue or color) and electron emission is given by the Einstein equation as where f is the frequency of the emission producing light ft is the lowestfrequency that will enable an electron to leave the photoelectric surface, It is Planck's constant=6.55 10- erg.-sec., m is the mass of the electron and V is the speed of the electron.
According to the relation, the electro velocity is proportional to the frequency of the light proutilized to determine the color of the light by" which the primary electrons are released from the photoelectric surface.
Important objects of the invention are the provision of a color analyzer which functions to in dicate or determine'color in response to the frequency of the applied light, and the provision of means whereby the output of an electron multiplier may be rendered independent of the intensity electron.
The device of Fig. 1 includes an electron-multiplier. A, an amplifier B, and a meter C which respondsto the current of the secondary electrons of the device A and is calibrated in terms of color.
Light falling on the photoelectric surface'D of the electron multiplier A enables some electrons to overcome the surface potential barrier and leaveit with a speed determined by the relation set forth by the above equation. These primary electrons travel to an electrode E.
The electrode E is of the type producing high secondary electron emission. The number of secondary electrons that leave it in response to each primary electron varies with the velocity of the. primary electron as indicated-by the curve of Fig. "2. If the potential applied to the electrode E is maintained at a value low enough-to keep the velocity of the secondary electrons below its maximum value, the current between the electrodes E and F is proportional (1) to the speed of the primary electrons striking theelectrode E and (2) to the number of primary electrons.
Since the device is required to respond only to the velocity of the primary electrons, some means must'be provided for neutralizing the effect otherwise produced by variationin the intensity of the light applied to the electrode D.
This undesired eifect is neutralized or compensated by means of a direct current amplifier bridge circuit. The different arms of this bridge circuit consist of (1) the 'plate circuit of the direct current amplifier B, (2) opposite sections of a resistor R2 and (3) the electrodes E and F of the device A. Connected across thediagonal of thebridge circuit are the meter C and a battery H polarized as indicated. The grid circuit of the amplifier B includes a resistor R1 and a battery G polarized as indicated. The potential applied to thegrid of the amplifier B is determined by the resultant difference between the voltage of the battery G and the voltage develaesase rectly proportional to the current between the.
electrodes D and E in the same way as the current between the electrodes E and F.
If the amplification factor Ip/Eg of the amplithe bridge is balanced fier B is made such that when light of the threshold frequency f is applied to the electrode D, no current flows through the meter C.
the invention are easily recognizable by those skilled in the art.
I claim as my invention:
1. The combination of a device wherein primary electrons ondary electrons are applied to an output electrode, a pair of impedance elements having a terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, and means for supplying to said terminal through the other of said elements component currents which are proportional respecof said primary electrons,
tively to the number and to the speed of said primary electrons.
2. The combination of a device wherein primary electrons derived from a cathode are projected on an emissive electrode from which sec- The application of light of higherfrequencies to the electrode D, however, produces-- derived from a cathode are pro- Hjected on an emissive electrode from which sec- 4. The combination of a device wherein primary electrons derived from a photoelectric electrode are projected on an emissive electrode from which secondary electrons are applied to an output electrode, a pair of impedance devices having a terminal in common, means including an amplifier responsive to said primary electrons for supplying current to said terminal through one of said elements, means for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said primary electrons, and
ondary electrons are applied to an output e1ec-.
trode, a pair of impedance elements having a terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, means for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said primary electrons, and means connected to said terminal for producing an indication proportional in value to said component current which is proportional to the speed of said primary electrons.
8. The combination of a device wherein primary electrons derived from a photoelectric electrode are projected on an em1ssive electrode from which secondary electrons are applied to an output electrode, a pair of impedance devices having a terminal in common, means'including an amplifier responsive to said primary electrons "for supplying current to said terminal through one of said elements, and means for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said Primary electrons and to the speed of said primary electrons.
put electrode, a pair of impedance devices having a terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, and means including said emissive and output electrodes for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said secondary electrons.
6. The combination of adevice wherein primary electrons derived from a photoelectric electrode are projected on an emissive electrode from which secondary electrons are applied to an output electrode, a pair of impedance devices having a-terminal in common, means for supplying to said terminal through one of said elements a current which is proportional to the number of said primary electrons, means including said emissive and output electrodes for supplying to said terminal through the other of said elements component currents which are proportional respectively to the number of said primary electrons and to the speed of said secondary electrons, and means for detecting the resultant difference between the currents supplied through said elements to said terminal.
'7. The combination of a device wherein primary electrons derived from a cathode are projected on an emissive electrode from which they are applied to an output electrode, and a bridge circuit including as two of its arms a pair of impedance elements having a terminal in common, as another of its arms said emissive and output electrodes and as still another of its arms means for producing a current proportional to the number of said primary electrons.
8. The combination of a device wherein primary electrons derived from a cathode are projected on an emissive electrode from which they are applied to an output electrode, and a bridge circuit including as two of its arms a pair of impedance elements having a terminal in common, as another of its arms said emissive and output electrodes and as still another of its arms an electron discharge device responsive only to the number of said primary electrons.
9. The combination of a device wherein primary electrons derived from a cathode are projected on an emissive electrode from which they are applied to an output electrode, a bridge circuit including as two of its arms a pair of impedance elements having a terminal in common,
as another of its arms said emissive and output connected between said terminal and a terminal common to said emissive electrode and the cathode of said electron discharge device for indicating a quantity proportional in value to the speed of said primary electrons.
GEORGE C. SZIKLAI.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS Number 10 Number Name Date Hardy Mar. 31, 1931 Razek et a1 June 26, 1934 Arnhym Oct. 27, 1936 Keck Oct. 24, 1939 Hillier Mar. 27, 1945 FOREIGN PATENTS Country Date Great Britain Dec. 20, 1938
US617857A 1945-09-21 1945-09-21 Color analyzing circuit Expired - Lifetime US2438586A (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2954466A (en) * 1956-07-09 1960-09-27 Jr John W Campbell Electron discharge apparatus
US3406291A (en) * 1965-01-13 1968-10-15 Rosemount Eng Co Ltd Method of establishing a voltage standard using a photoelectric tube

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1799134A (en) * 1928-11-21 1931-03-31 Gen Electric Mechanical integrating device
US1964365A (en) * 1931-01-08 1934-06-26 Razek Joseph Method of and apparatus for determining the intensity of colors
US2058941A (en) * 1935-03-30 1936-10-27 Akay Electron Co Converter for light rays
GB497457A (en) * 1936-09-18 1938-12-20 British Thomson Houston Co Ltd Improvements in and relating to electric discharge devices
US2177259A (en) * 1936-11-10 1939-10-24 Zeiss Carl Fa Emission type phototube
US2372422A (en) * 1944-02-17 1945-03-27 Rca Corp Electron microanalyzer

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1799134A (en) * 1928-11-21 1931-03-31 Gen Electric Mechanical integrating device
US1964365A (en) * 1931-01-08 1934-06-26 Razek Joseph Method of and apparatus for determining the intensity of colors
US2058941A (en) * 1935-03-30 1936-10-27 Akay Electron Co Converter for light rays
GB497457A (en) * 1936-09-18 1938-12-20 British Thomson Houston Co Ltd Improvements in and relating to electric discharge devices
US2177259A (en) * 1936-11-10 1939-10-24 Zeiss Carl Fa Emission type phototube
US2372422A (en) * 1944-02-17 1945-03-27 Rca Corp Electron microanalyzer

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2954466A (en) * 1956-07-09 1960-09-27 Jr John W Campbell Electron discharge apparatus
US3406291A (en) * 1965-01-13 1968-10-15 Rosemount Eng Co Ltd Method of establishing a voltage standard using a photoelectric tube

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