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The Tektronix 517 is a 50MHz scope [[introduced in 1950]] or [[introduced in 1951|1951]]. The power supply is an external box, like the [[507]], [[551]] and [[555]].
{{Oscilloscope Sidebar
The 517 does not take plug-ins. There is also a 517A
|manufacturer=Tektronix
The 517 closely resembles a scope that Tektronix developed under a contract
|series=
for the US military during 1949 and 1950.  (See link below.)
|model=517
|summary=50 MHz scope
|image=Tek 517a trace2.jpeg
|caption=Tektronix 517A at VintageTek Museum
|introduced=1951
|discontinued=1965
|designers=Logan Belleville;Dick Rhiger
|manuals=
* [[Media:IM-517.pdf|Early 517 Manual (IM-517)]] (OCR)
* [[Media:070-229.pdf|Later Manual (070-229) Covering the 517 and 517A]] (OCR)
* [[Media:070-0229-00.pdf|Latest Manual (070-0229-00) Covering the 517 and 517A]]
* [[Media:Tek_517_calibration_guide.pdf|Tektronix 517 Calibration Guide]] (OCR)
}}
The '''Tektronix 517''' is a 50 MHz scope [[introduced in 1950]] or [[introduced in 1951|1951]].
It was designed by [[Logan Belleville]] and [[Dick Rhiger]].
The power supply is an external box, like in the [[507]], [[551]] and [[555]].
The 517 does not take plug-ins. There is also a 517A (1955-1965).


Tektronix engineer Frank Hood recollects:
{{BeginSpecs}}
{{Spec | Bandwidth | AC (?) to 50 MHz (−3 dB)  }}
{{Spec | Rise time | 7 ns }}
{{Spec | Input Impedance | 170 Ω }}
{{Spec | Sweep Rates | 10 ns/div to 20 μs/div}}
{{Spec | Calibrator | ~25 kHz, 150 mV<sub>p-p</sub> to 50 V<sub>p-p</sub>, 4% accuracy }}
{{Spec | Power consumption | 1250 W }}
{{Spec | Weight  |
* Indicator: 76 pounds
* External Power Supply: 72 pounds }}
{{EndSpecs}}
 
=== Historic Context ===
The 517 closely resembles a scope that Tektronix developed under a contract for the US military during 1949 and 1950.  (See link below.)
 
Tektronix engineer [[Frank Hood]] recollects:
<blockquote>
<blockquote>
"A lot of progress was made in 1949 and 1950. Work was well underway by Logan Belleville, Dick Rhiger and Howard on the high speed scope, the 517. This used some brand new circuitry, distributed (or chain) amplifiers, using 16 to 20 tubes in each stage to get the power needed to handle the high frequencies. Our best prediction at that time was that there were only about 30 to 50 people in the whole world who had need of a scope with 60 to 100 megacycle bandwidth. As it turned out, when we brought out a higher speed scope, people were able to design equipment of greater bandwidth and needed even faster measuring instruments. The cycle was regenerative. Having faster, more accurate measuring tools created a demand for even more measuring tools. We eventually sold several thousand of this instrument."
"A lot of progress was made in 1949 and 1950.  
Work was well underway by [[Logan Belleville]], [[Dick Rhiger]] and [[Howard Vollum|Howard]] on the high speed scope, the 517.
 
This used some brand new circuitry, [[distributed amplifier|distributed (or chain) amplifiers]], using 16 to 20 tubes in each stage to get the power needed to handle the high frequencies.
 
Our best prediction at that time was that there were only about 30 to 50 people in the whole world who had need of a scope with 60 to 100 megacycle bandwidth.
As it turned out, when we brought out a higher speed scope, people were able to design equipment of greater bandwidth and needed even faster measuring instruments.
The cycle was regenerative. Having faster, more accurate measuring tools created a demand for even more measuring tools.
 
We eventually sold several thousand of this instrument."
</blockquote>
</blockquote>


The external power supply and oscilloscope are connected by a removable cable
==Internals==
with a Jones plug on one end and a Jones socket on the other end.   
=== External Power Supply ===
Units with serial numbers from 101 through 1739 use 12-pin Jones 2412 connectors;  
The external power supply and oscilloscope are connected by a removable cable with a Jones plug on one end and a Jones socket on the other end.   
after that it is a 16-pin Jones connector. (Was a 16-pin Jones connector used or
Units with serial numbers from 101 through 1739 use 12-pin Jones 2412 connectors; after that it is a 16-pin Jones connector.  
did they go directory from the 12-pin Jones connector to the 16-pin Amphenol power connector
''(Was a 16-pin Jones connector used or did they go directory from the 12-pin Jones connector to the 16-pin Amphenol power connector used by the [[555]]?)''
used by the [[555]]?) The voltages on the 12-pin connector are:
 
The voltages on the 12-pin connector are:


* Pin 1: +750V, regulated
* Pin 1: +750 V, regulated
* Pin 2: +475V, regulated
* Pin 2: +475 V, regulated
* Pin 3: +350V, unregulated
* Pin 3: +350 V, unregulated
* Pin 4: +225V, regulated
* Pin 4: +225 V, regulated
* Pin 5: +150V, regulated
* Pin 5: +150 V, regulated
* Pin 6: Ground
* Pin 6: Ground
* Pin 7: -250V, regulated
* Pin 7: −250 V, regulated
* Pin 8: +180V, unregulated
* Pin 8: +180 V, unregulated


Later 517A units uses the same cable as the [[551]] and [[555]].   
Later 517A units uses the same cable as the [[551]] and [[555]].   
Although they use the same cable, they are completely incompatible.
Although they use the same cable, they are completely incompatible – the voltages are different.   
The voltages are different.  The 517's external power supply
The 517's external power supply provides +750 V to the indicator unit.   
provides +750V to the indicator unit.  The highest voltage provided by
The highest voltage provided by the 555 and 551 power supplies is +500 V.
the 555 and 551 power supplies is +500V. Also, for example, the 517A
Also, for example, the 517A has +180 V on pin 8 of the 16-pin connector while the 555 and 551 have -150 V on pin 8.
has +180 on pin 8 of the 16-pin connector while the 555 and 551 have
 
-150V on pin 8.
At serial number 1740 a [[thermal cutoff]] was added.


=== Distributed Amplifiers ===
The 517 makes extensive use of the [[distributed amplifier]] concept.   
The 517 makes extensive use of the [[distributed amplifier]] concept.   
Originally the [[5XP]] CRT was used,  
Originally the [[5XP]] CRT was used, which has 38 V/cm vertical deflection sensitivity when operated with 24 kV acceleration voltage.  
which has 38V/cm vertical deflection sensitivity when operated with 24kV acceleration voltage.  
''(Is this correct?  It doesn't agree with the 5XP datasheet.)''
(Is this correct?  It doesn't agree with the 5XP datasheet.)
 
Since the vertical sensitivity at the input connector is 0.1V/cm, we can calculate that  
Since the vertical sensitivity at the input connector is 0.1 V/cm, we can calculate that the voltage gain from the input connector to the vertical deflection plates is 380.  
the voltage gain from the input connector to the vertical deflection plates is 380.  
For 4 cm deflection, a 152 V differential output swing is required.  There are DC blocking capacitors at various places in the signal path.   
For 4cm deflection, a 152-volt differential output swing is required.  There are DC blocking  
The slowest sweep is 20 μs/cm.  The 517 is not designed for low-frequency use.  
capacitors at various places in the signal path.  The slowest sweep is 20 us/cm.  The 517 is  
 
not designed for low-frequency use.  
The vertical signal path is as follows:
The vertical signal path is as follows:


Line 49: Line 90:
* Gain Stage 3: single-ended, seven sections, distributed, [[6AK5]] pentodes  
* Gain Stage 3: single-ended, seven sections, distributed, [[6AK5]] pentodes  
* Trig Pickoff: one common-cathode [[6CB6]] pentode
* Trig Pickoff: one common-cathode [[6CB6]] pentode
* Signal Delay: 51 feet of RG63U 125-ohm coaxial cable
* Signal Delay: 51 feet of RG63U 125 Ω coaxial cable (65 ns)
* Phase Splitter: single-ended in, differential out, three sections, distributed, [[6CB6]] pentode
* Phase Splitter: single-ended in, differential out, three sections, distributed, [[6CB6]] pentode
* Gain Stage 4: differential, six sections, distributed, [[6CB6]] pentodes
* Gain Stage 4: differential, six sections, distributed, [[6CB6]] pentodes
* Gain Stage 5: differential, twelve sections, distributed, [[6CB6]] pentodes
* Gain Stage 5: differential, twelve sections, distributed, [[6CB6]] pentodes


There is a trigger amplifier in the 517 which can take its input from  
There is a trigger amplifier in the 517 which can take its input from an external source, or from the trigger pickoff in the vertical pre-amp, or from the internal rate generator circuit.   
an external source, or  
The trigger amplifier circuit has five stages:
from the trigger pickoff in the vertical pre-amp, or  
from the internal rate generator circuit.   
The trigger amplifier circuit has
five stages:


* Phase Splitter: [[6J6]] dual-triode connected as a differential amplifier
* Phase Splitter: [[6J6]] dual-triode connected as a differential amplifier
Line 67: Line 104:
* Gain Stage 4: single-ended, common-cathode, [[6AG7]] pentode
* Gain Stage 4: single-ended, common-cathode, [[6AG7]] pentode


The 517 uses 24kV total acceleration voltage on the CRT.  This is generated by the Type 420 High Voltage
=== High Voltage Power Supply ===
Power Supply subsystem in the 517.  It uses a 1.8kHz oscillator to produce the high voltage, unlike
The 517 uses 24 kV total acceleration voltage on the CRT.   
other Tek scopes which use HV oscillators in the ultrasonic range.
This is generated by the [[420|Type 420]] High Voltage Power Supply subsystem in the 517.   
It uses a 1.8 kHz oscillator to produce the high voltage, unlike other Tek scopes which use HV oscillators in the ultrasonic range.
The power consumption of a 517 is 1250 watts.  The indicator unit weighs 76 pounds and the external
power supply weighs 72 pounds. 
 
517 units with serial numbers 101 through 925 use the DuMont 5XP CRT. 
Later units use a Tek-made CRT, the T517PxH/T54PxH, where "x" designates
the [[phosphor]] type: 1, 2, 7, 11, or 16.  The 5XP has three anode connections:
6.6kV, 13.3kV, and 20kV.  The Tek-made CRT has just one anode connection, 20kV,
and has 15 V/cm sensitivity at 24kV total acceleration voltage.


The 517 has a switch on the front panel that selects between normal vertical sensitivity,
The 517 has a switch on the front panel that selects between normal vertical sensitivity, which uses the full 24 kV acceleration voltage,  
which uses the full 24kV acceleration voltage, and "X2" mode, which drops the acceleration
and "×2" mode, which drops the acceleration voltage to 12 kV for a doubling of the vertical sensitivity.   
voltage to 12kV for a doubling of the vertical sensitivity.  The control works by  
The control works by switching the voltage division ratio of the feedback to the error amplifier in the HV supply.
switching the the voltage division ratio of the feedback to the error amplifier in the HV supply.


The 517 might be the only Tektronix instrument to have a part made of wood.
== CRTs Used in the 517 ==
There is a wood support for a large electrolytic capacitor, C826, which filters
517 units with serial numbers 101 through 925 use the [[5XP|DuMont 5XP CRT]]. 
the probe power.
Later units use a Tek-made CRT, the [[T517|T517PxH/T54PxH]], where "x" designates the [[phosphor]] type: 1, 2, 7, 11, or 16.
The 5XP used [[multi-band acceleration]] and has three anode connections, at 6.6 kV, 13.3 kV, and 20 kV. 
The Tek-made CRT has just one anode connection, 20 kV, and has 15 V/cm sensitivity at 24 kV total acceleration voltage.


In 1965, following the introduction of the 50MHz [[547]], the
The 517 might be the only Tektronix instrument to have a part made of wood - a support for a large electrolytic capacitor, C826, which filters probe power.
517 was discontinued.  The 547 uses a non-distributed solid-state vertical
(The [[437-0065-00‎‎]] carrying case also has wood parts.)
amplifier, [[tunnel diodes|tunnel diode]] triggering, and a 6.5 V/cm CRT,
thereby achieving good performance with
lower cost, size, weight, complexity, and power consumption than the 517.


== Comparison of 517 with 547 ==
In 1965, following the introduction of the 50 MHz [[547]], the 517 was discontinued.
The 547 uses a non-distributed solid-state vertical amplifier, [[tunnel diodes|tunnel diode]] triggering, and a 6.5 V/cm CRT, thereby achieving good performance with lower cost, size, weight, complexity, and power consumption than the 517.


{| border="1" style="text-align: center;"
{| border="1" class="wikitable" style="text-align: center;"
|+ Comparison of 517A with 547
|+ Comparison of 517A with 547
! scope="col" |
! scope="col" |
! scope="col" | 517A
! scope="col" width="33%" | 517A
! scope="col" | 547 with 1A1
! scope="col" width="33%" | 547 with 1A1
|-
|-
! scope="col" | Bandwidth
! scope="col" | Bandwidth
| 50MHz
| 50 MHz
| 50MHz
| 50 MHz
|-
|-
! scope="col" | Sensitivity
! scope="col" | Sensitivity
Line 118: Line 148:
|-
|-
! scope="row" | Weight
! scope="row" | Weight
| 148 pounds
| 148 lb / 67 kg
| 71 pounds
| 71 lb / 32 kg
|-
|-
! scope="row" | Complexity
! scope="row" | Complexity
Line 126: Line 156:
|-
|-
! scope="row" | Power Consumption
! scope="row" | Power Consumption
| 1250 watts
| 1250 W
| 510 watts
| 510 W
|}
|}


Some 517 modification kits are listed on page 181 of the 1959 catalog.
Some 517 modification kits are listed on page 181 of the 1959 catalog.


Tek sold the [[108]] pulse generator as a tool for maintaining the 517,
Tek sold the [[108]] pulse generator as a tool for maintaining the 517, since a fast scope requires a fast pulse generator to test it.
since a fast scope requires a fast pulse generator to test it.
 
The [[P170CF]] cathode-follower probe was designed for use with the 517.
 
== Links==
* [https://vintagetek.org/517-oscilloscope/ Tektronix 517] @ vintagetek.org
* [https://w140.com/tektronix_milspec_high_speed_scope_OCR.pdf Final Report on Tektronix MILSPEC High Speed Scope (PDF, cleaned up and OCR)]
* [https://w140.com/tektronix_milspec_high_speed_scope.pdf Final Report on Tektronix MILSPEC High Speed Scope (5MB, PDF, cleaned up)]
* [https://w140.com/MILSPEC_High_Speed_Scope.pdf Final Report on Tektronix MILSPEC High Speed Scope (220MB, PDF, original)]
* [https://w140.com/flynn_johnson_fast_gray_wedge.pdf Flynn and Johnson "Fast Grey Wedge Analyzer for High Input Rates"]
* [https://w140.com/thomas_and_hearst-measurement_of_exploding_wire_energy.pdf Thomas and Hearst, "An Electronic Scheme for Measurement of Exploding Wire Energy"]


* [http://w140.com/tektronix_milspec_high_speed_scope_OCR.pdf Final Report on Tektronix MILSPEC High Speed Scope (PDF, cleaned up and OCR)]
==Pictures of 517 ==
* [http://w140.com/tektronix_milspec_high_speed_scope.pdf Final Report on Tektronix MILSPEC High Speed Scope (5MB, PDF, cleaned up)]  
<gallery>
* [http://w140.com/MILSPEC_High_Speed_Scope.pdf Final Report on Tektronix MILSPEC High Speed Scope (220MB, PDF, original)]
517_cat_whole.jpg|front
* [http://w140.com/tek_517_calibration.pdf Tektronix 517 Calibration Guide]
517_cat_int_left.jpg|bottom internal
* [http://w140.com/tek_517_early.pdf Early 517 Manual (PDF)]
517_cat_int_right.jpg|right internal
* [http://w140.com/tek_517_early_OCR.pdf Early 517 Manual (PDF, OCR)]
517_cat_int_top.jpg|top internal
* [http://w140.com/tek_517_517a_v2.pdf Later Manual Covering the 517 and 517A (PDF)]
517_cat_ps_int.jpg|power supply internal
* [http://w140.com/tek_517_517a_OCR.pdf Later Manual Covering the 517 and 517A (PDF, OCR)]
517 power connector.jpg|12-pin Jones socket on power supply
* [http://w140.com/flynn_johnson_fast_gray_wedge.pdf Flynn and Johnson "Fast Grey Wedge Analyzer for High Input Rates"]
Jones 12pin male.jpg|12-pin Jones plug
* [http://w140.com/thomas_and_hearst-measurement_of_exploding_wire_energy.pdf Thomas and Hearst, "An Electronic Scheme for Measurement of Exploding Wire Energy"]
Tek 517 jones plug.jpg|Original Tek 517 cable with Jones plug
Jones 12m inside.jpg|12-pin Jones plug inside
Tek 517 420 hv.jpg|High voltage supply
Tek 517 front.jpg|Front view
Tek 517 indicator jones.jpg|12-pin Jones connector on indicator unit
Tek 517 left.jpg|Left internal view
Tek 517 vert output.jpg|Distributed vertical output amplifier
Tek 517 wood cap support.jpg|Wooden support for capacitor C826
Tek crt table.png|Tek CRT Reference Chart
517 trig amp underside.jpg
517 vert stages one through three.jpg
517 4th vert stage.jpg
517 right internals.jpg
517 timing switch 2.jpg
517 timing switch 1.jpg
517 power test point.jpg
517 hv osc.jpg
Tek 517a vert pre.png | Vertical pre-amplifier circuit
Tek 517a vert amp.png | Vertical amplifier circuit
Tek 517a trigger amp.png | Trigger amplifier circuit
Tek 517 late sweep.png |
Tek 517a crt circuit.png | CRT circuit
Tek 517a trigger rate gen.png |
Tek 517 hvps2.png | High-voltage power supply circuit
517 ps fan.jpg
517 ps bottom left.jpg
517 ps bottom right.jpg
517 ps front left int.jpg
517 ps right rear bottom.jpg
517 ps bottom.jpg
517 ps right int.jpg
517 assembly2.jpg
B170_A.JPG| [[B170-V|B170-V 170 Ω attenuator]]
Tek 517 ad.jpg
Tek 517A ad from Electronics Magazine 1955-12.jpg | Tek 517A ad from Electronics Magazine December 1955
517a rear vert interface.jpg|Direct CRT access mod
517a single sweep controls.jpg|Single-sweep mod
Tek 517 735 on cart.jpg
Tek 517 735 left.jpg
Tek 517 735 front.jpg
Tek 517 735 front upper.jpg
Tek 517 735 front lower.jpg
Tek517 Scope01.jpg
Tek517 Scope02.jpg
Tek517 Scope03.jpg
Tek517 Scope04.jpg
Tek517 Scope05.jpg
Tek 517 lvps internal.jpg
517 PowerSupply01.jpg
517 Cable PS-Scope.jpg
517 Cable Conn.jpg
517 Cable Conn2.jpg
Tek 517 with 5xp crt.jpg|517 with [[5XP]] CRT
Tek 517 right internal 5xp.jpg|517 with [[5XP]] CRT
Tek 517 early rear chassis.jpg
Tek 517 early bottom.jpg
Tek 517 early bottom rear.jpg
Tek 517 early bottom front.jpg
Tek 517 crt gun connections.jpg
</gallery>


==Pictures of 517A ==
<gallery>
<gallery>
Image:517_cat_whole.jpg|front
517A_1.JPG |517A Front
Image:517_cat_int_left.jpg|bottom internal
517A_2.JPG |517A Power Supply
Image:517_cat_int_right.jpg|right internal
6_57.JPG |517A with cart
Image:517_cat_int_top.jpg|top internal
Image:517_cat_ps_int.jpg|power supply internal
Image:517 power connector.jpg|12-pin Jones socket on power supply
Image:Jones 12pin male.jpg|12-pin Jones plug
Image:Jones 12m inside.jpg|12-pin Jones plug inside
Image:Tek 517 420 hv.jpg|High voltage supply
Image:Tek 517 front.jpg|Front view
Image:Tek 517 indicator jones.jpg|12-pin Jones connector on indicator unit
Image:Tek 517 left.jpg|Left internal view
Image:Tek 517 vert output.jpg|Distributed vertical output amplifier
Image:Tek 517 wood cap support.jpg|Wooden support for capacitor C826
Image:Tek crt table.png|Tek CRT Reference Chart
Image:517 trig amp underside.jpg
Image:517 vert stages one through three.jpg
Image:517 4th vert stage.jpg
Image:517 right internals.jpg
Image:517 timing switch 2.jpg
Image:517 timing switch 1.jpg
Image:517 power test point.jpg
Image:517 hv osc.jpg
Image:Tek 517a vert pre.png
Image:Tek 517a vert amp.png
Image:Tek 517a trigger amp.png
Image:Tek 517 late sweep.png
Image:Tek 517a crt circuit.png
Image:Tek 517a trigger rate gen.png
Image:517 ps fan.jpg
Image:517 ps bottom left.jpg
Image:517 ps bottom right.jpg
Image:517 ps front left int.jpg
Image:517 ps right rear bottom.jpg
Image:517 ps bottom.jpg
Image:517 ps right int.jpg
Image:517 assembly2.jpg
Image:B170_A.JPG| 170 ohms Attenuator
File:Tek 517 ad.jpg
</gallery>
</gallery>
==Components==
{{Parts|517}}
{{Parts|517A}}
[[Category:Monolithic tube scopes]]

Latest revision as of 12:31, 1 September 2024

Tektronix 517
50 MHz scope
Tektronix 517A at VintageTek Museum

Produced from 1951 to 1965

Manuals
Manuals – Specifications – Links – Pictures

The Tektronix 517 is a 50 MHz scope introduced in 1950 or 1951. It was designed by Logan Belleville and Dick Rhiger. The power supply is an external box, like in the 507, 551 and 555. The 517 does not take plug-ins. There is also a 517A (1955-1965).

Key Specifications

Bandwidth AC (?) to 50 MHz (−3 dB)
Rise time 7 ns
Input Impedance 170 Ω
Sweep Rates 10 ns/div to 20 μs/div
Calibrator ~25 kHz, 150 mVp-p to 50 Vp-p, 4% accuracy
Power consumption 1250 W
Weight
  • Indicator: 76 pounds
  • External Power Supply: 72 pounds

Historic Context

The 517 closely resembles a scope that Tektronix developed under a contract for the US military during 1949 and 1950. (See link below.)

Tektronix engineer Frank Hood recollects:

"A lot of progress was made in 1949 and 1950. Work was well underway by Logan Belleville, Dick Rhiger and Howard on the high speed scope, the 517.

This used some brand new circuitry, distributed (or chain) amplifiers, using 16 to 20 tubes in each stage to get the power needed to handle the high frequencies.

Our best prediction at that time was that there were only about 30 to 50 people in the whole world who had need of a scope with 60 to 100 megacycle bandwidth. As it turned out, when we brought out a higher speed scope, people were able to design equipment of greater bandwidth and needed even faster measuring instruments. The cycle was regenerative. Having faster, more accurate measuring tools created a demand for even more measuring tools.

We eventually sold several thousand of this instrument."

Internals

External Power Supply

The external power supply and oscilloscope are connected by a removable cable with a Jones plug on one end and a Jones socket on the other end. Units with serial numbers from 101 through 1739 use 12-pin Jones 2412 connectors; after that it is a 16-pin Jones connector. (Was a 16-pin Jones connector used or did they go directory from the 12-pin Jones connector to the 16-pin Amphenol power connector used by the 555?)

The voltages on the 12-pin connector are:

  • Pin 1: +750 V, regulated
  • Pin 2: +475 V, regulated
  • Pin 3: +350 V, unregulated
  • Pin 4: +225 V, regulated
  • Pin 5: +150 V, regulated
  • Pin 6: Ground
  • Pin 7: −250 V, regulated
  • Pin 8: +180 V, unregulated

Later 517A units uses the same cable as the 551 and 555. Although they use the same cable, they are completely incompatible – the voltages are different. The 517's external power supply provides +750 V to the indicator unit. The highest voltage provided by the 555 and 551 power supplies is +500 V. Also, for example, the 517A has +180 V on pin 8 of the 16-pin connector while the 555 and 551 have -150 V on pin 8.

At serial number 1740 a thermal cutoff was added.

Distributed Amplifiers

The 517 makes extensive use of the distributed amplifier concept. Originally the 5XP CRT was used, which has 38 V/cm vertical deflection sensitivity when operated with 24 kV acceleration voltage. (Is this correct? It doesn't agree with the 5XP datasheet.)

Since the vertical sensitivity at the input connector is 0.1 V/cm, we can calculate that the voltage gain from the input connector to the vertical deflection plates is 380. For 4 cm deflection, a 152 V differential output swing is required. There are DC blocking capacitors at various places in the signal path. The slowest sweep is 20 μs/cm. The 517 is not designed for low-frequency use.

The vertical signal path is as follows:

  • Optional B170-V external input attenuator
  • Gain Stage 1: single-ended, six sections, distributed, 6AK5 pentodes
  • Gain Stage 2: single-ended, six sections, distributed, 6AK5 pentodes
  • Gain Stage 3: single-ended, seven sections, distributed, 6AK5 pentodes
  • Trig Pickoff: one common-cathode 6CB6 pentode
  • Signal Delay: 51 feet of RG63U 125 Ω coaxial cable (65 ns)
  • Phase Splitter: single-ended in, differential out, three sections, distributed, 6CB6 pentode
  • Gain Stage 4: differential, six sections, distributed, 6CB6 pentodes
  • Gain Stage 5: differential, twelve sections, distributed, 6CB6 pentodes

There is a trigger amplifier in the 517 which can take its input from an external source, or from the trigger pickoff in the vertical pre-amp, or from the internal rate generator circuit. The trigger amplifier circuit has five stages:

  • Phase Splitter: 6J6 dual-triode connected as a differential amplifier
  • Gain Stage 1: single-ended, three sections, distributed, 6AK5 pentodes
  • Gain Stage 2: single-ended, three sections, distributed, 6AK5 pentodes
  • Gain Stage 3: single-ended, common-cathode, 6AG7 pentode
  • Gain Stage 4: single-ended, common-cathode, 6AG7 pentode

High Voltage Power Supply

The 517 uses 24 kV total acceleration voltage on the CRT. This is generated by the Type 420 High Voltage Power Supply subsystem in the 517. It uses a 1.8 kHz oscillator to produce the high voltage, unlike other Tek scopes which use HV oscillators in the ultrasonic range.

The 517 has a switch on the front panel that selects between normal vertical sensitivity, which uses the full 24 kV acceleration voltage, and "×2" mode, which drops the acceleration voltage to 12 kV for a doubling of the vertical sensitivity. The control works by switching the voltage division ratio of the feedback to the error amplifier in the HV supply.

CRTs Used in the 517

517 units with serial numbers 101 through 925 use the DuMont 5XP CRT. Later units use a Tek-made CRT, the T517PxH/T54PxH, where "x" designates the phosphor type: 1, 2, 7, 11, or 16. The 5XP used multi-band acceleration and has three anode connections, at 6.6 kV, 13.3 kV, and 20 kV. The Tek-made CRT has just one anode connection, 20 kV, and has 15 V/cm sensitivity at 24 kV total acceleration voltage.

The 517 might be the only Tektronix instrument to have a part made of wood - a support for a large electrolytic capacitor, C826, which filters probe power. (The 437-0065-00‎‎ carrying case also has wood parts.)

Comparison of 517 with 547

In 1965, following the introduction of the 50 MHz 547, the 517 was discontinued. The 547 uses a non-distributed solid-state vertical amplifier, tunnel diode triggering, and a 6.5 V/cm CRT, thereby achieving good performance with lower cost, size, weight, complexity, and power consumption than the 517.

Comparison of 517A with 547
517A 547 with 1A1
Bandwidth 50 MHz 50 MHz
Sensitivity 50 mV/cm 50 mV/cm
Cost in 1964 $3500 $2475
Size scope + power supply all in one
Weight 148 lb / 67 kg 71 lb / 32 kg
Complexity 130 tubes 45 tubes
Power Consumption 1250 W 510 W

Some 517 modification kits are listed on page 181 of the 1959 catalog.

Tek sold the 108 pulse generator as a tool for maintaining the 517, since a fast scope requires a fast pulse generator to test it.

The P170CF cathode-follower probe was designed for use with the 517.

Links

Pictures of 517

Pictures of 517A

Components

Some Parts Used in the 517

Part Part Number(s) Class Description Used in
12A4 154-0037-00 Vacuum Tube (Pentode) miniature 6.5 W power pentode 517 517A
12AU7 154-041 154-0041-00 154-0287-00 Vacuum Tube (Dual Triode) dual medium-μ triode 104 104A 122 160 161 162 181 190 310 310A 316 317 3C66 502 502A 507 511A 512 516 517 517A 524 526 535 536 545 545A 545B 547 549 555 561 564 570 575 581 581A 585 585A C D E N Q Hickok 1825 Keithley 660A
5651 154-052 154-0052-00 154-0288-00 Gas Discharge Tube (Voltage regulator) 87 V voltage reference 128 160 310 310A 502 503 504 511A 512 516 517 524 526 531 531A 535 536 541 541A 543 543A 543B 545 545A 545B 570 549 581 581A 585 585A
5R4GY 154-0007-00 Vacuum Tube (Dual Rectifier) dual rectifier 517 517A
5XP CRT family of flat-faced 5" CRTs 513 517
6AG7 154-012 154-0012-00 Vacuum Tube (Pentode) 9 Watt power pentode 104 104A 105 112 511 511A 512 513 514 517 517A 524
6AK5 154-0014-00 154-0206-00 154-0084-00 Vacuum Tube (Pentode) RF pentode B C CA G K L ML S Z 517 517A 524
6AL5 154-016 154-0016-00 154-0038-00 Vacuum Tube (Dual Diode) high-perveance dual diode 163 181 190 1M1 310 310A 315 316 317 3B1 3B1S 3B2 3B3 3B5 502 502A 503 511 511A 512 516 517 517A 524 526 535 535A 545 545A 549 551 565 570 581 581A 585 585A C T Telequipment D52 Telequipment D56 Telequipment S52
6AN8 154-078 154-0078-00 Vacuum Tube (Triode/Pentode) triode-pentode combo 310 310A 316 317 360 502 502A 516 517 517A 526 565 570 575 N
6AQ5 154-017 154-0017-00 Vacuum Tube (Pentode) beam pentode 310 310A 316 360 507 511A 512 517 517A 524 536 570 575
6AS5 154-0018-00 Vacuum Tube (Pentode) 5.5 W beam pentode 517 517A 524
6AS7 154-020 154-0020-00 Vacuum Tube (Pentode) dual power triode 160 506 511A 512 513 517 517A 524 561 561A 561S 564
6AU5 154-021 154-0021-00 Vacuum Tube (Pentode) 10 W beam power pentode 507 513 516 517 517A 531 535 541 535 545 547 581 581A 585 585A
6AU6 154-0022-00 157-0073-00 157-0059-00 154-0284-00 Vacuum Tube (Pentode) RF pentode 107 160 181 190 60 2A60 72 3A72 3C66 310 310A 316 317 360 502 502A 506 511 511A 512 513 516 517 517A 524 526 529 RM529 531 531A 535 536 545 545A 546 547 549 555 561 561A 561S 564 565 567 570 575 581 581A 585 585A 80 C CA Q
6BH6 154-0026-00 154-0285-00 Vacuum Tube (Pentode) pentode 130 162 310 310A 512 517 517A 524 Nelson-Ross PSA-011
6C4 154-029 154-0029-00 Vacuum Tube (Triode) VHF triode 190 3B2 507 511 511A 517 517A Chemtrix 205
6CB6A 154-0030-00 Vacuum Tube (Pentode) pentode 105 112 316 317 503 504 513 517 517A 541 535 545 63 2A63
6J6 154-032 154-0032-00 Vacuum Tube (Dual Triode) high-frequency dual triode 104 104A 161 511 511A 512 517 517A
6X4 154-035 154-0035-00 Vacuum Tube (Dual Rectifier) dual rectifier 128 130 181 511A 512 517 517A 570


Some Parts Used in the 517A

Part Part Number(s) Class Description Used in
12A4 154-0037-00 Vacuum Tube (Pentode) miniature 6.5 W power pentode 517 517A
12AU7 154-041 154-0041-00 154-0287-00 Vacuum Tube (Dual Triode) dual medium-μ triode 104 104A 122 160 161 162 181 190 310 310A 316 317 3C66 502 502A 507 511A 512 516 517 517A 524 526 535 536 545 545A 545B 547 549 555 561 564 570 575 581 581A 585 585A C D E N Q Hickok 1825 Keithley 660A
12BH7 154-0046-00 Vacuum Tube (Dual Triode) dual triode 506 517A 561A 561S 564 567
5R4GY 154-0007-00 Vacuum Tube (Dual Rectifier) dual rectifier 517 517A
6AG7 154-012 154-0012-00 Vacuum Tube (Pentode) 9 Watt power pentode 104 104A 105 112 511 511A 512 513 514 517 517A 524
6AK5 154-0014-00 154-0206-00 154-0084-00 Vacuum Tube (Pentode) RF pentode B C CA G K L ML S Z 517 517A 524
6AL5 154-016 154-0016-00 154-0038-00 Vacuum Tube (Dual Diode) high-perveance dual diode 163 181 190 1M1 310 310A 315 316 317 3B1 3B1S 3B2 3B3 3B5 502 502A 503 511 511A 512 516 517 517A 524 526 535 535A 545 545A 549 551 565 570 581 581A 585 585A C T Telequipment D52 Telequipment D56 Telequipment S52
6AN8 154-078 154-0078-00 Vacuum Tube (Triode/Pentode) triode-pentode combo 310 310A 316 317 360 502 502A 516 517 517A 526 565 570 575 N
6AQ5 154-017 154-0017-00 Vacuum Tube (Pentode) beam pentode 310 310A 316 360 507 511A 512 517 517A 524 536 570 575
6AS5 154-0018-00 Vacuum Tube (Pentode) 5.5 W beam pentode 517 517A 524
6AS7 154-020 154-0020-00 Vacuum Tube (Pentode) dual power triode 160 506 511A 512 513 517 517A 524 561 561A 561S 564
6AU5 154-021 154-0021-00 Vacuum Tube (Pentode) 10 W beam power pentode 507 513 516 517 517A 531 535 541 535 545 547 581 581A 585 585A
6AU6 154-0022-00 157-0073-00 157-0059-00 154-0284-00 Vacuum Tube (Pentode) RF pentode 107 160 181 190 60 2A60 72 3A72 3C66 310 310A 316 317 360 502 502A 506 511 511A 512 513 516 517 517A 524 526 529 RM529 531 531A 535 536 545 545A 546 547 549 555 561 561A 561S 564 565 567 570 575 581 581A 585 585A 80 C CA Q
6BH6 154-0026-00 154-0285-00 Vacuum Tube (Pentode) pentode 130 162 310 310A 512 517 517A 524 Nelson-Ross PSA-011
6C4 154-029 154-0029-00 Vacuum Tube (Triode) VHF triode 190 3B2 507 511 511A 517 517A Chemtrix 205
6CB6A 154-0030-00 Vacuum Tube (Pentode) pentode 105 112 316 317 503 504 513 517 517A 541 535 545 63 2A63
6J6 154-032 154-0032-00 Vacuum Tube (Dual Triode) high-frequency dual triode 104 104A 161 511 511A 512 517 517A
6X4 154-035 154-0035-00 Vacuum Tube (Dual Rectifier) dual rectifier 128 130 181 511A 512 517 517A 570
T517 154-0105-00 154-0107-00 154-0108-00 154-0109-00 154-0128-00 CRT family of CRTs 517A