Distributed deflection plates: Difference between revisions

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[[File:Distributed deflection plates.jpg|300px|thumb|right|Distributed vertical deflection plates and delay lines in a [[T581]] CRT (beam direction left to right)]]
[[File:Distributed deflection plates.jpg|300px|thumb|right|Distributed vertical deflection plates and delay lines in a [[T581]] CRT (beam direction left to right)]]
[[File:Distributed deflection schematic.jpg|thumb|300px|right|Simplified schematic of distributed deflection structure]]
[[File:Distributed deflection schematic.jpg|thumb|300px|right|Simplified schematic of distributed deflection structure]]
In conventional [[CRT]]s, a trade/off exists between acceleration voltage, deflection sensitivity and frequency response.
In [[CRT]]s, a trade/off exists between writing rate, deflection sensitivity and spot size.  Within a given technology (e.g. mono acceleration, post deflection acceleration or microchannel plate (MCP)), these three characteristics can be traded off against each other.  Improve one and the others suffer.  Improve the technology and all three can be improved simultaneously.  Writing rate is important to observe single short-lived events, but is not important for repetitive signals.  Spot size is important in showing detail in the waveform.  Sensitivity is important mostly to permit greater bandwidth in vertical amplifiers.


As signal frequency increases, the acceleration voltage needs to be increased as well in order to achieve sufficient beam brightness.
CRTs have a finite frequency response and distributed deflection structures extend the CRT's bandwidth as well as aid the vertical amplifier by virtually eliminating the capacitive load on the vertical amplifier.  
This in turn reduces deflection sensitivity.  To increase sensitivity again, the deflection plates need to be made longer, however, because the electron beam has a finite speed, making the plates too long means that by the time the beam reaches the end of the plate, the driving voltage is  already out of phase compared to the time the beam entered the deflection plate structure. In other words, when the drive voltage was going up at the time the beam entered the plate area, by the time it is leaving, the drive voltage will be going down again, pushing the beam back to the center, i.e. sensitivity for higher frequencies falls off sharply.


One solution to this problem is to segment the deflection plates into multiple pairs, each driven by a signal delayed just long enough to match the speed of the electron beam passing through the segmented structure.  This is achieved through a delay line, typically a lumped-constant line built into the tube, where coils are placed between the plate segments, and the plate segments form constant capacitances.  
The CRT's frequency response is not as simple as an RLC circuit.  A voltage step applied to the deflection plates simultaneously affects all the electrons between the plates.  Those that are just exiting the plates see nothing as they continue on their way to the phosphor for display.  Those that are at the entrance to the plates feel the effects of all voltage changes that take place during their transit through the plates.  However, they bear the memory of any deflection plate voltage changes during their journey through the plates.  The effects of any deflection plate voltage changes are delayed in proportion to their distance from the exit simply because it takes longer for the electrons to travel from the entrance to the exit of the plates.  This is what makes the frequency response complex.
 
For example, if it takes 1 ns for an electron to travel the length of the plates (usually one on each side of the electron beam) and a 1 GHz sine wave is applied between the plates, the full 360 degrees of the sine wave causes the electron to move up and down from entrance to exit.  When the drive voltage was going up at the time the beam entered the deflection plate area, by the time it is leaving, the drive voltage will be going down again, pushing the beam back to the center, i.e. the sensitivity is zero at this frequency.
 
Making the transit time shorter by shortening up the deflection plate improves the bandwidth, but reduces the deflection sensitivity by the same factor.  The distributed deflection plate structure is a way around this, extending the bandwidth without reducing the deflection sensitivityThere is no performance trade off.
 
In the distributed deflection plate structure, the original deflection plates are cut up into individual segments.  The capacitance of the deflection plates can then be made part of a lumped delay line by adding inductance between each of the segmented plates. These inductors inductors are inside the CRT.
 
Signals in a transmission line travel slowly.  If done correctly, the electron beam velocity equals the signal velocity down the delay line.  This reduces the time the electron beam spends between any particular deflection plate pair very short.  Yet the electrons keep seeing the same voltage no matter where they are along the structure.
 
The lumped delay line is terminated at the end of the deflection structure outside the CRT.  The end of this delay line needs to be terminated to prevent the drive signal being reflected back through the line.  In Tektronix scopes, the termination resistor can often be seen attached to a second pair of vertical deflection terminals on the side of the CRT, which bring out the end of the transmission line. The transmission line has absorbed the plate capacitance.  This means the vertical amplifier is driving a resistive load and not the capacitance of a long deflection plate.
[[File:Tek7844-v-b2.jpg|300px|thumb|right|Vertical termination resistor (l) and amplifier (r) in a [[7844]]]]
[[File:Tek7844-v-b2.jpg|300px|thumb|right|Vertical termination resistor (l) and amplifier (r) in a [[7844]]]]


The end of this delay line needs to be terminated to prevent the drive signal being reflected back through the line. In Tektronix scopes, the termination resistor can often be seen attached to a second pair of vertical deflection terminals on the side of the CRT, which bring out the end of the transmission line.
Distributed deflection plates reduce the capacitance seen by the driving amplifier, however, the terminated transmission line presents a much lower impedance than unterminated capacitive plates would.  While better matched to semiconductor amplifiers, driving low impedances from tube amplifiers presented challenges, as cathode followers were not able to provide sufficient bandwidth.  The problem was solved - at quite some expense - by using a [[distributed amplifier]].


==History==
==History==

Revision as of 20:52, 10 December 2023

Distributed vertical deflection plates and delay lines in a T581 CRT (beam direction left to right)
Simplified schematic of distributed deflection structure

In CRTs, a trade/off exists between writing rate, deflection sensitivity and spot size. Within a given technology (e.g. mono acceleration, post deflection acceleration or microchannel plate (MCP)), these three characteristics can be traded off against each other. Improve one and the others suffer. Improve the technology and all three can be improved simultaneously. Writing rate is important to observe single short-lived events, but is not important for repetitive signals. Spot size is important in showing detail in the waveform. Sensitivity is important mostly to permit greater bandwidth in vertical amplifiers.

CRTs have a finite frequency response and distributed deflection structures extend the CRT's bandwidth as well as aid the vertical amplifier by virtually eliminating the capacitive load on the vertical amplifier.

The CRT's frequency response is not as simple as an RLC circuit. A voltage step applied to the deflection plates simultaneously affects all the electrons between the plates. Those that are just exiting the plates see nothing as they continue on their way to the phosphor for display. Those that are at the entrance to the plates feel the effects of all voltage changes that take place during their transit through the plates. However, they bear the memory of any deflection plate voltage changes during their journey through the plates. The effects of any deflection plate voltage changes are delayed in proportion to their distance from the exit simply because it takes longer for the electrons to travel from the entrance to the exit of the plates. This is what makes the frequency response complex.

For example, if it takes 1 ns for an electron to travel the length of the plates (usually one on each side of the electron beam) and a 1 GHz sine wave is applied between the plates, the full 360 degrees of the sine wave causes the electron to move up and down from entrance to exit. When the drive voltage was going up at the time the beam entered the deflection plate area, by the time it is leaving, the drive voltage will be going down again, pushing the beam back to the center, i.e. the sensitivity is zero at this frequency.

Making the transit time shorter by shortening up the deflection plate improves the bandwidth, but reduces the deflection sensitivity by the same factor. The distributed deflection plate structure is a way around this, extending the bandwidth without reducing the deflection sensitivity. There is no performance trade off.

In the distributed deflection plate structure, the original deflection plates are cut up into individual segments. The capacitance of the deflection plates can then be made part of a lumped delay line by adding inductance between each of the segmented plates. These inductors inductors are inside the CRT.

Signals in a transmission line travel slowly. If done correctly, the electron beam velocity equals the signal velocity down the delay line. This reduces the time the electron beam spends between any particular deflection plate pair very short. Yet the electrons keep seeing the same voltage no matter where they are along the structure.

The lumped delay line is terminated at the end of the deflection structure outside the CRT. The end of this delay line needs to be terminated to prevent the drive signal being reflected back through the line. In Tektronix scopes, the termination resistor can often be seen attached to a second pair of vertical deflection terminals on the side of the CRT, which bring out the end of the transmission line. The transmission line has absorbed the plate capacitance. This means the vertical amplifier is driving a resistive load and not the capacitance of a long deflection plate.

Vertical termination resistor (l) and amplifier (r) in a 7844


History

Distributed deflection plates were introduced in the 580-series scopes in the late 1950s. Transistorized scopes followed with the upgrade of the 50 MHz 453 to the 150 MHz model 454 in 1967.

Typically, only the vertical deflection plates are distributed. An exception is the 7104 due to the high horizontal system bandwidth required (350 MHz).

Use of Distributed Deflection Plates
Model Distributed Y plates Distributed X plates
11301 yes no
11302 yes no
2445 yes no
2465 yes no
2467 yes no
453 no no
454 yes no
465 no no
475 yes no
485 yes no
519 yes no
53x no no
54x no no
55x no no
56x no no
58x yes no
7403 no no
7503 no no
7504 no no
7603 no no
7612D no no
7704 yes no
7704A yes no
7844 yes no
7854 yes no
7903 yes no
7904 yes no
7904A yes no
7912 yes no
7103 yes yes
7104 yes yes
7250 yes yes
SCD1000 yes yes
SCD5000 yes yes

Literature