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The '''Tektronix 067-0681-01''' is a pulse generator for adjusting the  
{{Instrument Sidebar
transient response of high frequency oscilloscopes such as the [[475]],  
|class=Calibrator
[[485]], [[7A11]], [[7A24]], [[7A19]]/[[7904]], and [[7A29]]/[[7104]].   
|manufacturer=Tektronix
|series=
|model=067-0681-01
|summary=Pulse Generator
|image=Tek 067-0681-01 front.jpg
|caption=067-0681-01 Tunnel Diode Pulser
|introduced=(?)
|discontinued=(?)
|designers=John Addis
|manuals=
* [[Media:062-1571-02.pdf|Tektronix 067-0681-01 Datasheet]]
* [[Media:Tek 067-0681 01 mod m40227.pdf|Modification #40227 for 067-0681-01]]
* [[Media:062-1571-01.pdf|December 1974 Revision Datasheet]]
* [[Media:062-1571-02.pdf|June 1981 Revision of Datasheet]]
 
}}
The '''Tektronix 067-0681-01''' is a pulse generator for adjusting the transient response of high frequency oscilloscopes such as the [[475]], [[485]], [[7A11]], [[7A24]], [[7A19]]/[[7904]], and [[7A29]]/[[7104]].   
It was designed by [[John Addis]].
It was designed by [[John Addis]].


It takes in a 60 to 100 V<sub>pp</sub> rectangular waveform  (e.g.  
{{MissingSpecs}}
from the calibrator output of an oscilloscope) and produces a 250 mV<sub>pp</sub>  
It takes in a 60 to 100 V<sub>pp</sub> rectangular waveform  (e.g. from the calibrator output of an oscilloscope) and produces a 250 mV<sub>pp</sub> rectangular waveform with rise time less than or equal to 125 picoseconds.   
rectangular waveform with rise time less than or equal to 125 picoseconds.   


The output pulse is produced by a 10 mA, 2 pF [[tunnel diodes|tunnel diode]],  
The output pulse is produced by a 10 mA, 2 pF [[tunnel diodes|tunnel diode]], part number [[152-0177-02]].
part number [[152-0177-02]].


The input and output connectors are [[Connectors#BNC|BNC]].
The input and output connectors are [[BNC]].The gender of the pulse output connector is appropriate for connecting directly to a BNC input of an oscilloscope (i.e., with no cable between the pulse generator and  
The gender of the pulse output connector is appropriate for connecting directly to  
a BNC input of an oscilloscope (i.e., with no cable between the pulse generator and  
the oscilloscope to spoil the risetime).
the oscilloscope to spoil the risetime).


A regular BNC cable is typically used for connecting the input that drives
A regular BNC cable is typically used for connecting the input that drives the 067-0681-01.  The risetime of the input to to the 067-0681-01 is not important.
the 067-0681-01.  The risetime of the input to to the 067-0681-01 is not
important.


==Circuit==
==Links==
* [http://www.amplifier.cd/Test_Equipment/Tektronix/Tektronix_other/Tunnel_Diode-Pulser/Tunnel_Diode_Pulser.html 067-0681-01 @ amplifier.cd]


The circuit starts with a DC restorer.  The output of the DC restorer turns a current  
==Internals==
source on and off.  The current produced by the current source (at the collector of PNP Q1)  
 
is set by controlling the emitter current using 6.3V zener diode CR3, R1, R2, and Vbe of Q3.   
The circuit starts with a DC restorer.  The output of the DC restorer turns a current source on and off.   
The current produced by the current source (at the collector of PNP Q1) is set by controlling the emitter current using 6.3 V Zener diode CR3, R1, R2, and V<sub>BE</sub> of Q3.   


R1 is a 200 Ω potentiometer (assume 100 Ω).  R2 is 390 Ω.
R1 is a 200 Ω potentiometer (assume 100 Ω).  R2 is 390 Ω.
Line 30: Line 42:
* I<sub>E</sub> (input waveform high) = (6.2 V - 0.7 V) / (100 Ω + 390 Ω) = 11.2 mA  
* I<sub>E</sub> (input waveform high) = (6.2 V - 0.7 V) / (100 Ω + 390 Ω) = 11.2 mA  


Q1 is Tektronix part number [[151-0410-00]] which is a 2N5087.
Q1 is Tektronix part number [[151-0410-00]], a 2N5087, which has a minimum beta of 250, so we can assume I<sub>C</sub> = I<sub>E</sub>.
The 2N5087 has a minimum beta of 250, so we can assume I<sub>C</sub> = I<sub>E</sub>.


Assume the tunnel diode is in its low-voltage state (70 mV) and I<sub>C</sub> of Q1 is 11.2 mA.
Assume the tunnel diode is in its low-voltage state (70 mV) and I<sub>C</sub> of Q1 is 11.2 mA. I<sub>C</sub> splits between the tunnel diode and R7, which is 43 Ω).
I<sub>C</sub> splits between the tunnel diode and R7, which is 43 Ω).


Assume the output is terminated by a 50 Ω load.  The current in R7 is  
Assume the output is terminated by a 50 Ω load.  The current in R7 is  
Line 40: Line 50:
* I<sub>R7</sub> (tunnel diode off, input waveform high) = 70 mV / (43+50) Ω = 0.75 mA.
* I<sub>R7</sub> (tunnel diode off, input waveform high) = 70 mV / (43+50) Ω = 0.75 mA.


So the tunnel diode gets 11.2 mA - 0.75 mA = 10.45 mA.  This is enough to  
So the tunnel diode gets 11.2 mA - 0.75 mA = 10.45 mA.  This is enough to switch the tunnel diode, even near the high end of its peak current tolerance range.  
switch the tunnel diode, even near the high end of its peak current tolerance range.  


After the tunnel diode switches to the high voltage state, more current (about 4 mA)  
After the tunnel diode switches to the high voltage state, more current (about 4 mA) is diverted into the load instead of the tunnel diode.
is diverted into the load instead of the tunnel diode.


Between the collector of the switched current source transistor Q1 and the output tunnel  
Between the collector of the switched current source transistor Q1 and the output tunnel diode, there is a chain of three 1 kΩ composition resistors in series.   
diode, there is a chain of three 1 kΩ composition resistors in series.  The purpose of this  
The purpose of this unusual design is almost certainly to reduce parasitic reactances that could slow the output pulse by coupling the tunnel diode to the transistor's capacitance, and could cause the output to ring, resulting in flat-top aberrations.
unusual design is almost certainly to reduce parasitic reactances that could slow the  
output pulse by coupling the tunnel diode to the transistor's capacitance, and could
cause the output to ring, resulting in flat-top aberrations.


===Output===
===Output===
The dynamic resistance of the tunnel diode in the high voltage state is low, but not
The dynamic resistance of the tunnel diode in the high voltage state is low, but not low enough for the diode to be modeled as a rock-solid voltage source.
low enough for the diode to be modeled as a rock-solid voltage source.
It is approximated in theory by
It is approximated in theory by


* r_d = 0.025 V / 0.006 A = 4.2 Ω  
* r<sub>d</sub> = 25 mV / 6 mA = 4.2 Ω  


Empirical measurements were closer to 7 Ω.  This, plus the 43 Ω output resistor,  
Empirical measurements were closer to 7 Ω.  This, plus the 43 Ω output resistor, makes for a 50 Ω output resistance when the tunnel diode is in the high-voltage state.   
makes for a 50 Ω output resistance when the tunnel diode is in the high-voltage state.   
To prevent the 43 Ω output resistor from appearing inductive and spoiling the flat top of the output waveform, the resistor is actually mounted inside the BNC output connector.
To prevent the 43 Ω output resistor from appearing inductive and spoiling the flat top  
The center conductor of the connector has a small hole to accept the 43 Ω resistor’s lead.   
of the output waveform, the resistor is actually mounted inside the BNC output connector.
Because of this, the resonant frequency of the TD and its parasitics is around 5 GHz and well damped, though the exact resonant frequency depends on exact lead length of components which varies somewhat during production.   
The center conductor of the connector has a small hole to accept the 43 Ω  
resistor’s lead.  Because of this, the resonant frequency of the  
TD and its parasitics is around 5 GHz and well damped, though the  
exact resonant frequency depends on exact lead length of components
which varies somewhat during production.   


For any scope with less than about 1.5 GHz BW, the ring would likely be invisible.   
For any scope with less than about 1.5 GHz BW, the ring would likely be invisible.   


==Data sheet==
==Pictures==
* [http://w140.com/tek_067-0681-01.pdf Tektronix 067-0681-01 Datasheet (PDF)]
<gallery>
 
Tek 067-0681-01 front.jpg
067-0681-01 1.jpg
067-0681-01 2.jpg
067-0681-01 3.jpg
Tek 067-0681-01 schematic diagram.png
</gallery>


[[Category:Pulse generators]]
[[Category:Pulse generators]]
[[Category:Calibration fixtures]]

Latest revision as of 04:33, 25 October 2023

Tektronix 067-0681-01
Pulse Generator
067-0681-01 Tunnel Diode Pulser

Produced from (?) to (?)

Manuals
Manuals – Specifications – Links – Pictures

The Tektronix 067-0681-01 is a pulse generator for adjusting the transient response of high frequency oscilloscopes such as the 475, 485, 7A11, 7A24, 7A19/7904, and 7A29/7104. It was designed by John Addis.

Key Specifications

  • please add

It takes in a 60 to 100 Vpp rectangular waveform (e.g. from the calibrator output of an oscilloscope) and produces a 250 mVpp rectangular waveform with rise time less than or equal to 125 picoseconds.

The output pulse is produced by a 10 mA, 2 pF tunnel diode, part number 152-0177-02.

The input and output connectors are BNC.The gender of the pulse output connector is appropriate for connecting directly to a BNC input of an oscilloscope (i.e., with no cable between the pulse generator and the oscilloscope to spoil the risetime).

A regular BNC cable is typically used for connecting the input that drives the 067-0681-01. The risetime of the input to to the 067-0681-01 is not important.

Links

Internals

The circuit starts with a DC restorer. The output of the DC restorer turns a current source on and off. The current produced by the current source (at the collector of PNP Q1) is set by controlling the emitter current using 6.3 V Zener diode CR3, R1, R2, and VBE of Q3.

R1 is a 200 Ω potentiometer (assume 100 Ω). R2 is 390 Ω.

  • IE (input waveform high) = (6.2 V - 0.7 V) / (100 Ω + 390 Ω) = 11.2 mA

Q1 is Tektronix part number 151-0410-00, a 2N5087, which has a minimum beta of 250, so we can assume IC = IE.

Assume the tunnel diode is in its low-voltage state (70 mV) and IC of Q1 is 11.2 mA. IC splits between the tunnel diode and R7, which is 43 Ω).

Assume the output is terminated by a 50 Ω load. The current in R7 is

  • IR7 (tunnel diode off, input waveform high) = 70 mV / (43+50) Ω = 0.75 mA.

So the tunnel diode gets 11.2 mA - 0.75 mA = 10.45 mA. This is enough to switch the tunnel diode, even near the high end of its peak current tolerance range.

After the tunnel diode switches to the high voltage state, more current (about 4 mA) is diverted into the load instead of the tunnel diode.

Between the collector of the switched current source transistor Q1 and the output tunnel diode, there is a chain of three 1 kΩ composition resistors in series. The purpose of this unusual design is almost certainly to reduce parasitic reactances that could slow the output pulse by coupling the tunnel diode to the transistor's capacitance, and could cause the output to ring, resulting in flat-top aberrations.

Output

The dynamic resistance of the tunnel diode in the high voltage state is low, but not low enough for the diode to be modeled as a rock-solid voltage source. It is approximated in theory by

  • rd = 25 mV / 6 mA = 4.2 Ω

Empirical measurements were closer to 7 Ω. This, plus the 43 Ω output resistor, makes for a 50 Ω output resistance when the tunnel diode is in the high-voltage state. To prevent the 43 Ω output resistor from appearing inductive and spoiling the flat top of the output waveform, the resistor is actually mounted inside the BNC output connector. The center conductor of the connector has a small hole to accept the 43 Ω resistor’s lead. Because of this, the resonant frequency of the TD and its parasitics is around 5 GHz and well damped, though the exact resonant frequency depends on exact lead length of components which varies somewhat during production.

For any scope with less than about 1.5 GHz BW, the ring would likely be invisible.

Pictures