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Published byJocelyn Brianna Hodges Modified over 5 years ago
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Fluoroscopy – Viewing Systems Optical Mirrors TV Camera & TV Camera Tubes Charge Coupled Devices (CCD) Based on: Principles of Radiographic Imaging, 3rd Ed. By: R. Carlton & A. Adler Radiologic Science for Technologists, 8th Ed. By: S. Bushong Syllabus on Fluoroscopy Radiation Protection, 6th Rev. By: Radiologic Health Branch – Certification Unit PPT created by Jed Miles, BSRS, RT(R), CRT-CA
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Video Viewing System Closed circuit video with TV monitor is the most commonly used fluoroscopic viewing system Contained system, eliminates outside and background broadcast interference System includes: Video camera attached to the output side of the II Camera Control Unit Amplifies the video signal Synchronizes video signal between the TV camera and TV monitor Display monitor Cathode Ray Tube (CRT) or LCD Associated cabling
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Video (TV) Camera Tubes
Several types of camera tubes, main difference is the phosphor used as the target material Vidicon tube Most often used in fluoroscopic imaging chains Relatively slow response time, produces image lag Less quantum mottle due to lag producing signal averaging Plumbicon tube Less often used (mainly used in cardiac cath labs) Faster response time and low lag Produces better contrast More quantum mottle – low lag does not provide signal averaging from previous frame Image-Orthicon: very expensive – rarely used Charged Coupled Device (CCD) Solid-state semiconductor – not a vacuum tube
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Charge-Coupled Devices (CCD)
Semiconducting device capable of storing a charge from light photons striking a photosensitive surface When light strikes the photoelectric cathode of the CCD, electrons are released proportionally to the intensity of the incident light Advantages: Extremely fast discharge time – no image lag Useful for high speed imaging applications More sensitive than video tubes – operate at lower voltages – prolongs useful life Acceptable resolution Not prone to damage from rough handling
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Video (TV) Camera Tubes
Camera tubes contain: Cathode with a control grid Series of electromagnetic focusing coils Series of electrostatic deflecting coils Anode with face plate Signal plate Target
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Video Camera Tubes – Cathode End
Electron Gun - Consists of heated filament assembly that supplies a constant electron current across the tube via thermionic emission Thermionic emission is flow of electrons from a metal or metal oxide surface, caused by thermal energy Control grid – shapes the electrons into a stream or beam Also helps accelerate electrons to anode end of tube Electrostatic Grids - further accelerate and focus the electron beam toward anode end Focusing Coils – focus the electron beam into a pencil point stream Deflecting coils (in pairs) deflect pencil beam to scan target in path known as a raster pattern
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Video Camera Tubes – Anode End
Beam is decelerated by wire mesh-like structure in front of the target assembly This arrangement brings the electron beam to a near standstill where it is straightened to strike the target in a perpendicular fashion
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Video Camera Tubes – Target Assembly
Consists of three layers sandwiched together Face plate or window – is the thin part of the glass envelope closest to the output phosphor of the image intensifier Signal plate – consists of a thin film of metal or graphite charged with a positive voltage Is thin enough to transmit light from intensifier Yet thick enough to conduct an electronic signal Target or photoconductive layer – a photoconductive layer coated on the inside surface of the signal plate
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Target Assembly - Construction
Target or Photoconductive layer Consists of a thin insulating mica coating in which globules of a light sensitive photoconductive material are suspended in a matrix Vidicon tubes use antimony trisulfide (Sb2S2) Plumbicon tubes use lead oxide (PbO) Globules approximately inch (0.025 mm) in diameter Size of globules determines resolving power of camera tube (smaller = increased resolution) Light photons interacts with this layer When illuminated becomes photoconductive and releases electrons - when dark acts as an insulator
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Target Assembly – How it Works
Light from output phosphor of image intensifier tube arrives, transmitted through window and signal plate to target material Antimony trisulfide (or lead oxide) globules absorbs light photons from II output screen and emit electrons Light is absorbed by globules, electrons released to anode and removed from tube (equivalent to intensity of absorbed light) Loss of electrons creates positive charge at globule Electron gun’s beam scans target, discharges globules, causing current flow in signal plate Sequential charging and discharging of globules results in modulated current flow in signal plate creating varying amplitudes of video signal
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Target Assembly
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Another Way of Stating it…
As electron beam is incident on a globule some of its electrons will be conducted through target to signal plate and conducted out of tube as video signal If area (globule) of target is dark (i.e. bone attenuated the x-ray beam) there will be less video signal Magnitude of video signal is proportional to intensity of light from the intensifier Sequential discharging of the globules releases signal plate’s charge as a pulsed signal This “pulsing” is the varying amplitude of the video signal Full explanation (click link)
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