Radio Vision
The machines here shown are the laboratory models used in the development of Radio Vision and Radio Movies for the reception in the home of broadcast studio performances, i. e., dancing girls, public speakers, pantomime, marionettes, motion pictures; and, by remote control, outdoor events, sports, etc.
The lower illustration shows a 10″ disc rotating in front of a prismatic ring, synchronized by a variable speed of the motor. The light is in the round box at the top of the standard behind the lens carrier, and shines through lenses and prism (onto a picture screen) as they pass, the light fluctuating in value with the incoming radio signals to make up a complete picture every one-sixteenth of a second.
The upper illustrated mechanism differs from the lower one in that it has a second overlapping prism for optical correction.
The casing enclosing the mechanism is not very large, and contains, besides the radio vision mechanism, the radio receiving set, and a loudspeaker, so that an entire opera in both action and music may be received.
The prismatic ring can be rotated to follow any moving object; e.g., a motion picture film; or if fitted with a high-reading automobile speedometer the speed of an airplane or dirigible can be read directly off a dial by the navigating officer.
The prismatic ring can be rotated to follow any moving object; e.g., a motion picture film; or if fitted with a high-reading automobile speedometer the speed of an airplane or dirigible can be read directly off a dial by the navigating officer.
The prismatic ring can be rotated to follow any moving object; e.g., a motion picture film; or if fitted with a high-reading automobile speedometer the speed of an airplane or dirigible can be read directly off a dial by the navigating officer.
[Photographs]
glowing filament offset hollow cylinder filled with light NEW LIGHT SOURCES FOR RADIO vibrating gold leaf electroscope for blinking a constant light source spark plug light source
[Drawing]
_Fig. 1._ _Fig. 2._The rotation of the discAcarrying lensesb,c,d, etc., sweepsthe image of the light sourceCacross the screenFin a horizontaldirection, while line displacement in a vertical directionis effected by reason of the changing angle of successive prismelements.
The rotation of the discAcarrying lensesb,c,d, etc., sweepsthe image of the light sourceCacross the screenFin a horizontaldirection, while line displacement in a vertical directionis effected by reason of the changing angle of successive prismelements.
The rotation of the discAcarrying lensesb,c,d, etc., sweepsthe image of the light sourceCacross the screenFin a horizontaldirection, while line displacement in a vertical directionis effected by reason of the changing angle of successive prismelements.
_Fig. 1._ _Fig. 2._The rotation of the discAcarrying lenses arranged in a spiral causes the lightLto sweep across the screenM. A revolution every sixteenth second gives a motion picture screen effect.
The rotation of the discAcarrying lenses arranged in a spiral causes the lightLto sweep across the screenM. A revolution every sixteenth second gives a motion picture screen effect.
The rotation of the discAcarrying lenses arranged in a spiral causes the lightLto sweep across the screenM. A revolution every sixteenth second gives a motion picture screen effect.
_Fig. 1._ _Fig. 2._Radio Motion Picture MechanismThe rotation of the drumAcarrying the lensesb,b′,b″, etc., causes the image of the light sourceSto sweep across the screenYin two directions. A complete rotation every sixteenth of a second is motion picture speed.
Radio Motion Picture MechanismThe rotation of the drumAcarrying the lensesb,b′,b″, etc., causes the image of the light sourceSto sweep across the screenYin two directions. A complete rotation every sixteenth of a second is motion picture speed.
Radio Motion Picture MechanismThe rotation of the drumAcarrying the lensesb,b′,b″, etc., causes the image of the light sourceSto sweep across the screenYin two directions. A complete rotation every sixteenth of a second is motion picture speed.
Radio Vision hook-up circuits.Ais the light cell. The upper circuit puts a “chopper” frequency onto the radio carrier wave by the inductive coupling.The lower diagram shows an intermediate frequency oscillator to be controlled by a light cell (not shown), the intermediate being put on the carrier wave.
Radio Vision hook-up circuits.Ais the light cell. The upper circuit puts a “chopper” frequency onto the radio carrier wave by the inductive coupling.The lower diagram shows an intermediate frequency oscillator to be controlled by a light cell (not shown), the intermediate being put on the carrier wave.
Radio Vision hook-up circuits.Ais the light cell. The upper circuit puts a “chopper” frequency onto the radio carrier wave by the inductive coupling.The lower diagram shows an intermediate frequency oscillator to be controlled by a light cell (not shown), the intermediate being put on the carrier wave.