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The Tektronix Type 6R1 is a plug-in for the [[567]] oscilloscope. It was later replaced by the [[6R1A]].   
{{Plugin Sidebar
The 6R1 provides digital readout of time and voltage measurements
|manufacturer=Tektronix
on waveforms.  The 6R1 (and the 567 in general) is oriented toward sampling measurements.   
|series=567
|type=6R1
|summary=Digital readout plug-in
|image=6r1_front.jpg
|caption=6R1 Front view
|introduced=1962
|discontinued=(?)
|designers=Sam McCutcheon
|manuals=
* [[Media:070-334.pdf|Tektronix 6R1 Manual]]
* [[Media:Tektronix 6R1 schematics.pdf|6R1 Schematics]]
* [[Media:Tek 6r1 spurious count oct 1963 service scope.pdf|Article in October 1963 Service Scope with a fix for spurious counts in 6R1]]
* [[Media:Tek 6r1 preliminary manual.pdf|Tektronix 6R1 Preliminary Manual]]
* [[Media:Tek 6r1 cal outline.pdf|Tektronix 6R1 Calibration Outline]] (OCR)
* [[Media:040-0342-00.pdf|Tektronix Mod Kit 040-0342-00 for the 6R1]]
}}
The '''Tektronix 6R1''' is a plug-in for the [[567]] oscilloscope.
It was later replaced by the [[6R1A]].   
The 6R1 provides digital readout of time and voltage measurements on waveforms.   
The 6R1 (and the 567 in general) is oriented toward sampling measurements.   
 
The basic building blocks of the 6R1 are a counter and comparators.   
The basic building blocks of the 6R1 are a counter and comparators.   
To digitize analog voltages, the counter and comparator
To digitize analog voltages, the counter and comparator are used as a ramp-compare ADC.   
are used as a ramp-compare ADC.   


The 6R1 contains digital logic but no integrated circuits.   
The 6R1 contains digital logic but no integrated circuits.   
Its logic is implemented using discrete bipolar transistors,  
Its functions are implemented using dozens of discrete bipolar transistors,  
vacuum tubes, and tunnel diodes.  Most of the digital signals
fourteen vacuum tubes (depending on version), and a few tunnel diodes.   
within the 6R1 use 0V to represented a "0" and 20V to represent a "1".   
 
Flip-flops (bistable multivibrators) are implemented in the 6R1 using  
Most of the digital signals within the 6R1 use 0 V to represent a "0" and 20 V to represent a "1".   
the classic cross-coupled transistor pair.  The counter is composed of  
Flip-flops (bistable multivibrators) are implemented in the 6R1 using the classic cross-coupled transistor pair.   
several of these flip-flop subcircuits,
The counter is composed of several of these flip-flop subcircuits, as are various other state machines in the 6R1.   
as are various other state machines in the 6R1.   
 
All of the active circuitry of the 6R1 is on small plug-in printed circuit boards.   
All of the active circuitry of the 6R1 is on small plug-in printed circuit boards.   
There are twelve different boards labeled A through L.   
There are twelve different boards labeled A through L.   
The 6R1 contains more than one of some of the boards,  
The 6R1 contains more than one of some of the boards, seventeen boards in total.
seventeen boards in total.
 
The digital display of the Tektronix 6R1 is composed of four Burroughs [[B5092]] Nixie tubes for the digits, and one Burroughs [[B5094]] Nixie tube for the units.
 
The [[3S2]] manual says:
<blockquote>
The Type 3S2 is compatible for operation with all Type
230 Digital Units and all Type 6R1A Digital Units. It is
compatible with all Type 6R1 Digital Units SN 695 and up.
The Type 6R1 Digital Units SN 101-694 require the installation
of Tektronix [[Media:040-0342-00.pdf|Modification Kit 040-0342-00]] when operating with
a Type 3S2.
</blockquote>
The [[3S1]] manual contains a similar note.
 
=6R1 Internals=


*Board A: COUNTER (6R1 has four of these)
* Board A: COUNTER (6R1 has four of these)
*Board B: DIVIDE BY 1,2,5
* Board B: DIVIDE BY 1,2,5
*Board C: MASTER GATE
* Board C: MASTER GATE
*Board D: SIGNAL COMPARATOR (6R1 has two of these)
* Board D: SIGNAL COMPARATOR (6R1 has two of these)
*Board E: VOLTMETER
* Board E: VOLTMETER
*Board F: UPPER LIMIT NO-GO
* Board F: UPPER LIMIT NO-GO
*Board G: LOWER LIMIT NO-GO
* Board G: LOWER LIMIT NO-GO
*Board H: LIGHT LIMIT DRIVER
* Board H: LIGHT LIMIT DRIVER
*Board I: DIVIDE BY 10  
* Board I: DIVIDE BY 10  
*Board J: ANALOG DISPLAY
* Board J: ANALOG DISPLAY
*Board K: 0% ZONE
* Board K: 0% ZONE
*Board L: MEMORY (6R1 has two of these)
* Board L: MEMORY (6R1 has two of these)


When a 6R1 is used in a 567 with a [[3T77]], the horizontal sweep signal is
When a 6R1 is used in a 567 with a [[3T77]], the horizontal sweep signal is generated by the staircase generator circuit in the 3T77.  
generated by the staircase generator circuit in the 3T77. From R184 in the
From R184 in the 3T77's staircase generator, the sweep signal is sent to the horizontal amplifier circuit of the 3T77, where it enters the sweep mode switch.   
3T77's staircase generator, the sweep signal is sent to the horizontal amplifier circuit
Assuming that the sweep mode switch is in the NORMAL or SINGLE DISPLAY positions, the sweep signal is sent out through R318 to pin 20 on P22, the connector on the rear of the 3T77.   
of the 3T77, where it enters the sweep mode switch.  Assuming that the sweep mode
The 567 carries the signal to pin 8 on P32 of the 6R1.  Within the 6R1, the sweep signal is carried to pin 7 of the 0% zone card.   
switch is in the NORMAL or SINGLE DISPLAY positions, the sweep signal is sent out
through R318 to pin 20 on P22, the connector on the rear of the 3T77.  The 567 carries
the signal to pin 8 on P32 of the 6R1.  Within the 6R1, the sweep signal is carried
to pin 7 of the 0% zone card.   


== Board K: 0% ZONE ==
== Board K: 0% ZONE ==
<gallery>
<gallery>
Image:6r1 board k top.jpg
6r1 board k top.jpg
Image:6r1 board k bottom.jpg
6r1 board k bottom.jpg
Image:6r1_board_k_outside.jpg
6r1_board_k_outside.jpg
Image:6r1 0-percent zone schem.png
6r1 0-percent zone schem.png
</gallery>
</gallery>


Line 71: Line 100:
== Board L: MEMORY ==
== Board L: MEMORY ==
<gallery>
<gallery>
Image:6r1 board l top.jpg
6r1 board l top.jpg
Image:6r1 board l bottom.jpg
6r1 board l bottom.jpg
Image:6r1_board_l_outside.jpg
6r1_board_l_outside.jpg
6r1 memory schem.png
</gallery>
</gallery>
The 6R1 contains two MEMORY boards, one for vertical input A and one for vertical input B.
The 6R1 contains two MEMORY boards, one for vertical input A and one for vertical input B.
Each MEMORY card contains two sample and hold circuits.
Each MEMORY card contains two sample and hold circuits.
The main purpose of the MEMORY card is to sample and hold its vertical signal during the
The main purpose of the MEMORY card is to sample and hold its vertical signal during the
0% and 100% zones.  One sampler on the MEMORY card captures the the signal voltage during the 0% zone.   
0% and 100% zones.  One sampler on the MEMORY card captures the signal voltage during the 0% zone.   
The other captures the signal voltage during the 100% zone.  The input to
The other captures the signal voltage during the 100% zone.  The input to
both of the the samplers is the output signal of the vertical plug-in.  Since this is a relatively  
both of the samplers is the output signal of the vertical plug-in.  Since this is a relatively  
slow-changing signal with a relatively long sampling time, each sampler circuit is simply a sampling gate  
slow-changing signal with a relatively long sampling time, each sampler circuit is simply a sampling gate  
(also known as a transmission gate or analog switch)  
(also known as a transmission gate or analog switch)  
Line 91: Line 121:
supply and splits approximately equally between the left diode path (D61 and D71) and the right
supply and splits approximately equally between the left diode path (D61 and D71) and the right
diode path (D62 and D72).  With both paths conducting, the bridge is "on" and the holding capacitor (C80)
diode path (D62 and D72).  With both paths conducting, the bridge is "on" and the holding capacitor (C80)
voltage converges to the vertical signal voltage.  When the 0% zone card detects the the sweep has
voltage converges to the vertical signal voltage.  When the 0% zone card detects that the sweep has
left the 0% zone, the +0% zone signal goes to 0 V and the -0% zone signal goes to 20 V.  This turns on
left the 0% zone, the +0% zone signal goes to 0 V and the -0% zone signal goes to 20 V.  This turns on
Q63 and Q73, which act as emitter-followers, lowering the voltage at the top of the sampling bridge
Q63 and Q73, which act as emitter-followers, lowering the voltage at the top of the sampling bridge
Line 97: Line 127:
bridge.  With D62 and D72 reverse-biased, current cannot flow through R80.  Assuming that the grid
bridge.  With D62 and D72 reverse-biased, current cannot flow through R80.  Assuming that the grid
current of V83 is zero, whatever charge is on the holding capacitor at the end of the sampling pulse
current of V83 is zero, whatever charge is on the holding capacitor at the end of the sampling pulse
is trapped on the the capacitor until the next sampling pulse.  (V_cap = Q_cap / C).
is trapped on the capacitor until the next sampling pulse.  (V_cap = Q_cap / C).


The 100% zone sample and hold circuit gets its sampling signals  
The 100% zone sample and hold circuit gets its sampling signals  
Line 133: Line 163:
== Board A: COUNTER (6R1 has four of these) ==
== Board A: COUNTER (6R1 has four of these) ==
<gallery>
<gallery>
Image:6r1 board a top.jpg
6r1 board a top.jpg
Image:6r1 board a bottom.jpg
6r1 board a bottom.jpg
Image:6r1_board_a_outside.jpg
6r1_board_a_outside.jpg
6r1 counter schem.png
</gallery>
</gallery>
Each COUNTER board contains four flip-flops and functions as one
Each COUNTER board contains four flip-flops and functions as one
Line 148: Line 179:
== Board B: DIVIDE BY 1,2,5 ==
== Board B: DIVIDE BY 1,2,5 ==
<gallery>
<gallery>
Image:6r1 board b top.jpg
6r1 board b top.jpg
Image:6r1 board b bottom.jpg
6r1 board b bottom.jpg
Image:6r1_board_b_outside.jpg
6r1_board_b_outside.jpg
6r1 divide by 1-2-5 schem.png
</gallery>
</gallery>
== Board C: MASTER GATE ==
== Board C: MASTER GATE ==
<gallery>
<gallery>
Image:6r1 board c top.jpg
6r1 board c top.jpg
Image:6r1 board c bottom.jpg
6r1 board c bottom.jpg
Image:6r1_board_c_outside.jpg
6r1_board_c_outside.jpg
6r1 master gate schem.png
</gallery>
</gallery>
== Board D: SIGNAL COMPARATOR (6R1 has two of these) ==
== Board D: SIGNAL COMPARATOR (6R1 has two of these) ==
<gallery>
<gallery>
Image:6r1 board d top.jpg
6r1 board d top.jpg
Image:6r1 board d bottom.jpg
6r1 board d bottom.jpg
Image:6r1_board_d_outside.jpg
6r1_board_d_outside.jpg
6r1 signal comparator schem.png
</gallery>
</gallery>
== Board E: VOLTMETER ==
== Board E: VOLTMETER ==
<gallery>
<gallery>
Image:6r1 board e top.jpg
6r1 board e top.jpg
Image:6r1 board e bottom.jpg
6r1 board e bottom.jpg
Image:6r1_board_e_outside.jpg
6r1_board_e_outside.jpg
6r1 voltmeter schem.png
</gallery>
</gallery>
== Board F: UPPER LIMIT NO-GO ==
== Board F: UPPER LIMIT NO-GO ==
<gallery>
<gallery>
Image:6r1 board f top.jpg
6r1 board f top.jpg
Image:6r1 board f bottom.jpg
6r1 board f bottom.jpg
Image:6r1_board_f_outside.jpg
6r1_board_f_outside.jpg
6r1 upper limit no-go schem.png
</gallery>
</gallery>
The UPPER LIMIT NO-GO circuit compares the current value of the four-digit decimal  
The UPPER LIMIT NO-GO circuit compares the current value of the four-digit decimal  
Line 183: Line 219:
== Board G: LOWER LIMIT NO-GO ==
== Board G: LOWER LIMIT NO-GO ==
<gallery>
<gallery>
Image:6r1 board g top.jpg
6r1 board g top.jpg
Image:6r1 board g bottom.jpg
6r1 board g bottom.jpg
Image:6r1_board_g_outside.jpg
6r1_board_g_outside.jpg
6r1 lower limit no-go schem.png
</gallery>
</gallery>
The LOWER LIMIT NO-GO circuit compares the current value of the  
The LOWER LIMIT NO-GO circuit compares the current value of the  
Line 195: Line 232:
== Board H: LIMIT LIGHT DRIVER ==
== Board H: LIMIT LIGHT DRIVER ==
<gallery>
<gallery>
Image:6r1 board h top.jpg
6r1 board h top.jpg
Image:6r1 board h bottom.jpg
6r1 board h bottom.jpg
Image:6r1_board_h_outside.jpg
6r1_board_h_outside.jpg
6r1 limit light driver schem.png
</gallery>
</gallery>
The LIMIT LIGHT DRIVER board gets inputs from the LOWER LIMIT NO-GO board and the
The LIMIT LIGHT DRIVER board gets inputs from the LOWER LIMIT NO-GO board and the
Line 210: Line 248:
== Board I: DIVIDE BY 10 ==
== Board I: DIVIDE BY 10 ==
<gallery>
<gallery>
Image:6r1 board i top.jpg
6r1 board i top.jpg
Image:6r1 board i bottom.jpg
6r1 board i bottom.jpg
Image:6r1_board_i_outside.jpg
6r1_board_i_outside.jpg
6r1 divide by 10 schem.png
</gallery>
</gallery>
== Board J: ANALOG DISPLAY ==
== Board J: ANALOG DISPLAY ==
<gallery>
<gallery>
Image:6r1 board j top.jpg
6r1 board j top.jpg
Image:6r1 board j bottom.jpg
6r1 board j bottom.jpg
Image:6r1_board_j_outside.jpg
6r1_board_j_outside.jpg
6r1 analog display schem.png
</gallery>
</gallery>
The ANALOG DISPLAY board is responsible for intensifying the trace during the 0% zone,
The ANALOG DISPLAY board is responsible for intensifying the trace during the 0% zone,
100% zone, and during the start-to-stop zone.
100% zone, and during the start-to-stop zone.


[http://w140.com/tek_6r1_schem.pdf 6R1 Schematics]
There is an extender plug-in, the [[067-0505-00]], that allows a 6R1 or 6R1A to be operated
outside the plug-in bay of the 567 for maintenance purposes.
There are extension cards, the 012-067 and 012-068 (shown below),
that allow the circuit cards in the 6R1 to be accessed for maintenance
while the instrument is powered up.


==Pictures==
<gallery>
<gallery>
Image:6r1_front.jpg|Front view
6r1_front.jpg|Front view
Image:6r1_right2.jpg|Right view
6r1_right2.jpg|Right view
Image:6r1_j33.jpg|Connector J33
6r1_j33.jpg|Connector J33
Image:6r1_j34.jpg|Connector J34
6r1 j33 schem.png|Connector J33 pinout
6r1_j34.jpg|Connector J34
6r1 j34 schem.png|Connector J34 pinout
6r1 timing stop switch schem.png|Timing stop switch
6r1 timing start switch schem.png|Timing start switch
6r1 resolution switch schem.png|Resolution switch
6r1 readout tubes schem.png|Readout tubes
6r1 plug-in circuit board connectors schem.png|Backplane wiring
6r1 mode switch schem.png|Mode switch
6r1 upper limit switches schem.png|Upper limit switches
6r1 lower limit switches schem.png|Lower limit switches
6r1 connectors to indicators unit schem.png|Connections to 567
Tek 012-067 012-068 1964 cat.jpg|012-067 and 012-068
</gallery>
</gallery>
==Components==
{{Parts|6R1}}
[[Category:560 series plugins]]

Latest revision as of 06:22, 6 December 2023

Tektronix 6R1
Digital readout plug-in
6R1 Front view

Compatible with 567

Produced from 1962 to (?)

Manuals
Manuals – Specifications – Links – Pictures

The Tektronix 6R1 is a plug-in for the 567 oscilloscope. It was later replaced by the 6R1A. The 6R1 provides digital readout of time and voltage measurements on waveforms. The 6R1 (and the 567 in general) is oriented toward sampling measurements.

The basic building blocks of the 6R1 are a counter and comparators. To digitize analog voltages, the counter and comparator are used as a ramp-compare ADC.

The 6R1 contains digital logic but no integrated circuits. Its functions are implemented using dozens of discrete bipolar transistors, fourteen vacuum tubes (depending on version), and a few tunnel diodes.

Most of the digital signals within the 6R1 use 0 V to represent a "0" and 20 V to represent a "1". Flip-flops (bistable multivibrators) are implemented in the 6R1 using the classic cross-coupled transistor pair. The counter is composed of several of these flip-flop subcircuits, as are various other state machines in the 6R1.

All of the active circuitry of the 6R1 is on small plug-in printed circuit boards. There are twelve different boards labeled A through L. The 6R1 contains more than one of some of the boards, seventeen boards in total.

The digital display of the Tektronix 6R1 is composed of four Burroughs B5092 Nixie tubes for the digits, and one Burroughs B5094 Nixie tube for the units.

The 3S2 manual says:

The Type 3S2 is compatible for operation with all Type 230 Digital Units and all Type 6R1A Digital Units. It is compatible with all Type 6R1 Digital Units SN 695 and up. The Type 6R1 Digital Units SN 101-694 require the installation of Tektronix Modification Kit 040-0342-00 when operating with a Type 3S2.

The 3S1 manual contains a similar note.

6R1 Internals

  • Board A: COUNTER (6R1 has four of these)
  • Board B: DIVIDE BY 1,2,5
  • Board C: MASTER GATE
  • Board D: SIGNAL COMPARATOR (6R1 has two of these)
  • Board E: VOLTMETER
  • Board F: UPPER LIMIT NO-GO
  • Board G: LOWER LIMIT NO-GO
  • Board H: LIGHT LIMIT DRIVER
  • Board I: DIVIDE BY 10
  • Board J: ANALOG DISPLAY
  • Board K: 0% ZONE
  • Board L: MEMORY (6R1 has two of these)

When a 6R1 is used in a 567 with a 3T77, the horizontal sweep signal is generated by the staircase generator circuit in the 3T77. From R184 in the 3T77's staircase generator, the sweep signal is sent to the horizontal amplifier circuit of the 3T77, where it enters the sweep mode switch. Assuming that the sweep mode switch is in the NORMAL or SINGLE DISPLAY positions, the sweep signal is sent out through R318 to pin 20 on P22, the connector on the rear of the 3T77. The 567 carries the signal to pin 8 on P32 of the 6R1. Within the 6R1, the sweep signal is carried to pin 7 of the 0% zone card.

Board K: 0% ZONE

The primary purpose if the 0% ZONE circuit is to produce a signal that instructs the memory circuits to sample and hold the voltages at their inputs during the first cm of the sweep. On the 0% ZONE card, the sweep signal which arrives on pin 7 is buffered by V43, a Nuvistor cathode-follower, and the buffered sweep signal is sent out from pin 10 of the 0% ZONE card. This is a secondary feature of the 0% zone card. To accomplish its main purpose, the 0% ZONE card compares the buffered sweep voltage with a fixed voltage, putting D43, a 2mA tunnel diode, into the high voltage state whenever the sweep signal is above about 5 V. Since the sweep signal goes from 0 V to 50 V for a complete sweep, 5V corresponds to a point 1 major division from the left edge of the display. The +GATE signal goes high at the beginning of each sweep and returns low at the end of each sweep. The +0% OUT signal is high only during the first cm of the sweep. The logic is +GATE AND NOT (SWEEP > 5V). When the sweep starts, Q23 pulls the top leg of R54 high, and since Q54 is off at the point, the voltage on the bottom leg of R54 also rises, raising the voltage at the base of buffer transistor Q63, which raises the +0% output. When the sweep voltage reaches 5V and the Q54 turns on, the voltage on the bottom leg of R54 drops to near 0 V. The buffer Q63 follows, and the +0% output falls. The -0% output signal is the logical complement of the +0% signal, generated by common-emitter inverter Q64.

Board L: MEMORY

The 6R1 contains two MEMORY boards, one for vertical input A and one for vertical input B. Each MEMORY card contains two sample and hold circuits. The main purpose of the MEMORY card is to sample and hold its vertical signal during the 0% and 100% zones. One sampler on the MEMORY card captures the signal voltage during the 0% zone. The other captures the signal voltage during the 100% zone. The input to both of the samplers is the output signal of the vertical plug-in. Since this is a relatively slow-changing signal with a relatively long sampling time, each sampler circuit is simply a sampling gate (also known as a transmission gate or analog switch) feeding a 1uF holding capacitor, the voltage on which is buffered by a Nuvistor cathode follower.

The 0% sample and hold circuit gets its sampling signal from the 0% ZONE card. When the 0% ZONE card detects that the sweep is within the 0% zone, the +0% zone signal is +20 V and the -0% zone signal is 0 V. This turns off Q63 and Q73. About 3.2mA flows from the +125 V supply and splits approximately equally between the left diode path (D61 and D71) and the right diode path (D62 and D72). With both paths conducting, the bridge is "on" and the holding capacitor (C80) voltage converges to the vertical signal voltage. When the 0% zone card detects that the sweep has left the 0% zone, the +0% zone signal goes to 0 V and the -0% zone signal goes to 20 V. This turns on Q63 and Q73, which act as emitter-followers, lowering the voltage at the top of the sampling bridge and raising the voltage at the bottom of the sampling bridge, reverse-biasing the diodes in the bridge. With D62 and D72 reverse-biased, current cannot flow through R80. Assuming that the grid current of V83 is zero, whatever charge is on the holding capacitor at the end of the sampling pulse is trapped on the capacitor until the next sampling pulse. (V_cap = Q_cap / C).

The 100% zone sample and hold circuit gets its sampling signals from the 100% zone detector circuit which is also on the MEMORY card. The purpose of the 100% zone detector circuit is to generate a logic signal that is true when the sweep is within the 100% zone. The horizontal position of the 100% zone is variable using the "A 100% ZONE SET" and "B 100% ZONE SET" controls on the front of the 6R1. One pin 12, the MEMORY card get the +GATE signal, which is high while the timing unit (3T77, for example) is sweeping. Between sweeps, the +GATE signal is low, 0V, which turns off Q3. With Q3 off, Q13 and Q23 have no collector current, so D13 and D23 have no current. When the sweep starts, the +GATE signal goes to +20V, and the emitter voltage of Q3 follows. Tunnel diodes D13 and D23 operate in a bistable mode. When the sweep ramp starts, both diodes are in their low-voltage state. When the sweep enters the left edge of the 100% zone, D23 switches to the high-voltage state, while D13 remains in the low-voltage state. This causes the base voltage of Q33 to rise, turning Q33 off, and it causes the base voltage of Q43 to fall, turning Q43 off. This turns on the sampling gate, as discussed above for the 0% sample and hold circuit. When the sweep ramp reaches a voltages the corresponds to the right edge of the 100% zone, D13 switches to the high-voltage state, turning on Q14, which turns off the sampling gate. The sampling gate connects the vertical input signal to the holding capacitor when D23 is in the high-voltage state and D13 is in the low-voltage state. At the end of the sweep, the +GATE signal goes down to 0V. That turns off Q3 and returns D13 and D23 to the original low-voltage state.

Board A: COUNTER (6R1 has four of these)

Each COUNTER board contains four flip-flops and functions as one digit of a decimal counter. Since the 6R1 has a four-digit decimal counter, it has four COUNTER boards. These boards have two functions aside from counting. First, they contain the NPN transistors that drive the Nixie tubes of the digital readout. Second, each COUNTER board contains a simple digital-to-analog converter (DAC) that produces a voltage proportional to the current count. This STAIRCASE voltage is used by the UPPER and LOWER LIMIT NO-GO boards.

Board B: DIVIDE BY 1,2,5

Board C: MASTER GATE

Board D: SIGNAL COMPARATOR (6R1 has two of these)

Board E: VOLTMETER

Board F: UPPER LIMIT NO-GO

The UPPER LIMIT NO-GO circuit compares the current value of the four-digit decimal counter with the upper limit set using the four-digit UPPER LIMIT SET control. If the count exceeds the limit, the UPPER LIMIT NO-GO board sends a signal to the LIMIT LIGHT DRIVER board, which lights the red lamp.

Board G: LOWER LIMIT NO-GO

The LOWER LIMIT NO-GO circuit compares the current value of the four-digit decimal counter with the lower limit set using the four-digit LOWER LIMIT SET control. If the count is less than the limit, the LOWER LIMIT NO-GO board sends a signal to the LIMIT LIGHT DRIVER board, which lights the green lamp.

Board H: LIMIT LIGHT DRIVER

The LIMIT LIGHT DRIVER board gets inputs from the LOWER LIMIT NO-GO board and the UPPER LIMIT NO-GO board. If the LOWER LIMIT NO-GO board asserts its output, the LIMIT LIGHT DRIVER lights the yellow lamp. If the UPPER LIMIT NO-GO board asserts its output, the LIMIT LIGHT DRIVER lights the red lamp. If neither NO-GO board asserts its output, the LIMIT LIGHT DRIVER lights the green lamp.

Board I: DIVIDE BY 10

Board J: ANALOG DISPLAY

The ANALOG DISPLAY board is responsible for intensifying the trace during the 0% zone, 100% zone, and during the start-to-stop zone.

There is an extender plug-in, the 067-0505-00, that allows a 6R1 or 6R1A to be operated outside the plug-in bay of the 567 for maintenance purposes. There are extension cards, the 012-067 and 012-068 (shown below), that allow the circuit cards in the 6R1 to be accessed for maintenance while the instrument is powered up.

Pictures

Components

Some Parts Used in the 6R1

Part Part Number(s) Class Description Used in
6CW4 154-0323-00 Vacuum Tube (Triode) Nuvistor triode 1A7 3A8 3B2 3S76 6R1 565 S-311
7586 154-0306-00 Vacuum Tube (Triode) Nuvistor triode M 1A1 1A2 1A5 10A2 10A2A 11B1 11B2A 321 321A 3A1 3A1S 3A3 3A5 3A6 3A7 3A8 3A74 3S76 3T77 3T77A 3B5 4S1 4S2 6R1 6R1A 9A1 9A2 82 86 S-311
B5092 154-327 154-0327-00 Gas Discharge Tube (Nixie tube) numeric Nixie tube 6R1 6R1A
B5094 154-326 154-0326-00 Gas Discharge Tube (Nixie tube) Nixie 6R1 6R1A