P6230: Difference between revisions
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{{Probe Sidebar | |||
[[File:P6230-1.jpg|thumb|right| | |manufacturer=Tektronix | ||
|model=P6230 | |||
|summary=1.5 GHz, 450:50 Ω passive probe | |||
|image=P6230-6.jpg | |||
|caption=Tektronix P6230 | |||
|for=50 Ω scope inputs | |||
|introduced=1984 | |||
|discontinued=(?) | |||
|manuals= | |||
* [[Media:070-4211-00.pdf|P6230 Operator manual]] (OCR) | |||
* [[Media:070-6027-00.pdf|P6231 Instruction manual]] (OCR) | |||
}} | |||
[[File:P6230-1.jpg|thumb|right|250px|P6230 termination box]] | |||
The '''Tektronix P6230''' and '''P6231''' are passive ×10 (450:50 Ω) probes with 1.5 GHz bandwidth and DC offset capability, intended to minimize DC probe-loading effect when used on logic circuits. | The '''Tektronix P6230''' and '''P6231''' are passive ×10 (450:50 Ω) probes with 1.5 GHz bandwidth and DC offset capability, intended to minimize DC probe-loading effect when used on logic circuits. | ||
The '''P6230''' has an offset control potentiometer in the termination box and connects to the scope, e.g. [[7000 series scopes]], through a [[BNC connector]] with ×10 readout pin. It can be powered from 7000 series mainframes having [[LEMO S-series connector]]s for probe power, or compatible units such as the [[1101]]. | The '''P6230''' has an offset control potentiometer in the termination box and connects to the scope, e.g. [[7000 series scopes]], through a [[BNC connector]] with ×10 readout pin. It can be powered from 7000 series mainframes having [[LEMO S-series connector]]s for probe power, or compatible units such as the [[1101]]. The [[7A42]] can measure the P6230's offset. | ||
The '''P6231''' | The '''P6231''' is a TekProbe Level 2 probe intended for 11000 series plugins such as the [[11A32]] or [[11A71]]. Offset control and power are provided by the scope mainframe through a [[Tekprobe BNC connector]]. | ||
The P6230/6231 shares accessories with many other Tektronix [[subminiature modular probes]] although the input hybrid is unique. Tip color is yellow, connector end color is blue, part number [[206-0279-00]]. Its end to end resistance is 400 Ω. | The P6230/6231 shares accessories with many other Tektronix [[subminiature modular probes]] although the input hybrid is unique. Tip color is yellow, connector end color is blue, part number [[206-0279-00]]. Its end to end resistance is 400 Ω. | ||
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{{Spec | Input Impedance | 450 Ω // 1.3 pF (1.6 pF guaranteed) }} | {{Spec | Input Impedance | 450 Ω // 1.3 pF (1.6 pF guaranteed) }} | ||
{{Spec | Signal delay | 8.7 ± 0.1 ns }} | {{Spec | Signal delay | 8.7 ± 0.1 ns }} | ||
{{Spec | DC | {{Spec | DC offset | −5 V ≤ (V<sub>signal</sub> + V<sub>offset</sub>) ≤ +5 V }} | ||
{{Spec | Features | | {{Spec | Features | | ||
* Readout Pin | * Readout Pin | ||
| Line 28: | Line 40: | ||
<blockquote> | <blockquote> | ||
The P6230 acts as a standard 500 Ω passive voltage probe with the additional capability of having an adjustable tip "nulling voltage." This feature reduces the dc-loading effects on the probe when it is used to measure signals whose mid-voltage value is other than zero volts, or in circuits where the termination impedance is returned to other than ground level. The Input Bias/Offset Voltage may be adjusted so that at a particular test-signal voltage both ends of the probe input-resistor are at equal potentials and no current is flowing through the resistor. | The P6230 acts as a standard 500 Ω passive voltage probe with the additional capability of having an adjustable tip "nulling voltage." This feature reduces the dc-loading effects on the probe when it is used to measure signals whose mid-voltage value is other than zero volts, or in circuits where the termination impedance is returned to other than ground level. The Input Bias/Offset Voltage may be adjusted so that at a particular test-signal voltage both ends of the probe input-resistor are at equal potentials and no current is flowing through the resistor. | ||
ECL logic is most commonly operated from a −5.2 V supply with V<sub>CC</sub> connected to ground. The output of an ECL gate is the emitter of an NPN emitter follower stage. The output is pulled down to a negative supply (about −2 V) with an external resistor (50 Ω to 100 Ω). Since speed is a major consideration in ECL designs, the interconnections between gates are often transmission lines, and the pull-down resistor doubles as a line termination. | |||
ECL logic is most commonly operated from a | |||
If a standard 500 Ω, 10× probe without the input Bias/Offset feature were used to examine an ECL output, the probe's 500 Ω resistance to ground would form a voltage divider with the gate's output-termination resistor. This divider can cause distortion of the output signal levels, shift the DC operation point of the output transistor, and reduce the gate's noise margin. | If a standard 500 Ω, 10× probe without the input Bias/Offset feature were used to examine an ECL output, the probe's 500 Ω resistance to ground would form a voltage divider with the gate's output-termination resistor. This divider can cause distortion of the output signal levels, shift the DC operation point of the output transistor, and reduce the gate's noise margin. | ||
The DC-load nulling capability of the P6230 helps to solve this problem. By adjusting the Input Bias/Offset Voltage to the ECL low level or to the termination voltage, the only effect of the probe resistance will be a small decrease in the ECL output-termination resistance. The effect of the probe on output voltage levels is negligible. | The DC-load nulling capability of the P6230 helps to solve this problem. By adjusting the Input Bias/Offset Voltage to the ECL low level or to the termination voltage, the only effect of the probe resistance will be a small decrease in the ECL output-termination resistance. The effect of the probe on output voltage levels is negligible. | ||
</blockquote> | </blockquote> | ||
| Line 41: | Line 50: | ||
==Links== | ==Links== | ||
* [http://www.barrytech.com/tektronix/probes/tekp6230.html P6230] / [http://www.barrytech.com/tektronix/probes/tekp6230.html P6231] @ barrytech.com (incorrectly described as active probe) | * [http://www.barrytech.com/tektronix/probes/tekp6230.html P6230] / [http://www.barrytech.com/tektronix/probes/tekp6230.html P6231] @ barrytech.com (incorrectly described as active probe) | ||
==Prices== | ==Prices== | ||
| Line 52: | Line 56: | ||
! Year | ! Year | ||
! 1984 | ! 1984 | ||
! 1987 | ! 1987 | ||
! 1989 | ! 1989 | ||
| Line 60: | Line 63: | ||
! P6230 Catalog price | ! P6230 Catalog price | ||
|align=right| $385 | |align=right| $385 | ||
|align=right| $395 | |align=right| $395 | ||
|align=right| $420 | |align=right| $420 | ||
| Line 66: | Line 68: | ||
|align=right| – | |align=right| – | ||
|- | |- | ||
! | ! In 2023 Dollars | ||
|align=right| $ | |align=right| $1,100 | ||
|align=right| $ | |align=right| $1,100 | ||
|align=right| $ | |align=right| $1,000 | ||
|align=right| $ | |align=right| $1,200 | ||
|align=right| – | |align=right| – | ||
|- | |- | ||
! P6231 Catalog price | ! P6231 Catalog price | ||
|align=right| – | |align=right| – | ||
|align=right| $410 | |align=right| $410 | ||
| Line 82: | Line 82: | ||
|align=right| $799 | |align=right| $799 | ||
|- | |- | ||
! | ! In 2023 Dollars | ||
|align=right| – | |align=right| – | ||
|align=right| $ | |align=right| $1,200 | ||
|align=right| $ | |align=right| $1,000 | ||
|align=right| $ | |align=right| $1,200 | ||
|align=right| $1, | |align=right| $1,600 | ||
|} | |} | ||
| Line 94: | Line 93: | ||
<gallery> | <gallery> | ||
P6230-1.jpg | P6230 compensation box | |||
P6230-2.jpg | P6230 Switchable terminator | |||
P6230-4.jpg | P6230 Compensation box interior | |||
P6230-5.jpg | P6230 Compensation box interior | |||
Tek p6231.jpg | P6231 | |||
P6230-6.jpg | P6230 probe tip with alligator clip ground lead | |||
206-0279-00.jpg | [[206-0279-00|Input hybrid]] | |||
P6230-3.jpg | Probe tip components | |||
P6230-7.jpg | Low-inductance ground lead | |||
P6230-8.jpg | |||
P6230-9.jpg | |||
P6230-10.jpg | Probe-to-PCB adapters | |||
P6230-11.jpg | Probe-to-PCB adapters | |||
P6230-circuit.jpg | P6230 circuit diagram | |||
P6230-impedance.jpg | P6230 input impedance graph | |||
</gallery> | </gallery> | ||
===Measurements=== | ===Measurements=== | ||
<gallery> | <gallery> | ||
P6230-rt1.jpg | P6230 Rise time measured on a [[7S12]] with [[S-52]] and [[S-4]] heads, P6230 ground sleeve connected directly at S-52 output (no ground lead) | |||
P6230-rt2.jpg | P6230 Rise time without ground lead: 9.2 * 20 ps = 184 ps (equiv. to 1.9 GHz bandwidth) | |||
P6230-rt3.jpg | Effect of using the "low inductance" ground lead - rise time 400 ps, bandwidth 875 MHz | |||
P6230-rt4.jpg | Using the 250 mm (9.8") alligator ground lead - severe pulse distortion, rise time ~3 ns (115 MHz)! | |||
P6230-bw.jpg | Bandwidth vs. grounding, from manual | |||
</gallery> | </gallery> | ||
[[Category:Subminiature modular probes]] | [[Category:Subminiature modular probes]] | ||
[[Category:50 | [[Category:50 Ω Oscilloscope probes]] | ||
Latest revision as of 01:37, 5 July 2024
The Tektronix P6230 and P6231 are passive ×10 (450:50 Ω) probes with 1.5 GHz bandwidth and DC offset capability, intended to minimize DC probe-loading effect when used on logic circuits.
The P6230 has an offset control potentiometer in the termination box and connects to the scope, e.g. 7000 series scopes, through a BNC connector with ×10 readout pin. It can be powered from 7000 series mainframes having LEMO S-series connectors for probe power, or compatible units such as the 1101. The 7A42 can measure the P6230's offset.
The P6231 is a TekProbe Level 2 probe intended for 11000 series plugins such as the 11A32 or 11A71. Offset control and power are provided by the scope mainframe through a Tekprobe BNC connector.
The P6230/6231 shares accessories with many other Tektronix subminiature modular probes although the input hybrid is unique. Tip color is yellow, connector end color is blue, part number 206-0279-00. Its end to end resistance is 400 Ω.
Key Specifications
| Bandwidth | DC to ≥ 1.5 GHz |
|---|---|
| Rise time | ≤ 230 ps |
| Attenuation | 10× |
| Input Impedance | 450 Ω // 1.3 pF (1.6 pF guaranteed) |
| Signal delay | 8.7 ± 0.1 ns |
| DC offset | −5 V ≤ (Vsignal + Voffset) ≤ +5 V |
| Features |
|
Internals
The P6230/6231 probes are sometimes described as FET probes or active probes, however, as the circuit diagram clearly shows, this is not correct. After the 400 Ω input hybrid, the AC component of the input signal is connected directly to the scope input through a 1 μF capacitor, then terminated in 50 Ω either in the scope input or the switchable terminator. The active circuit in the P623x, a standard NE5532 dual opamp, has the function of restoring and offsetting the input signal's low-frequency and DC components. This approach is similar to the feed-beside technique used in the 7104 scope and 7A29 amplifier.
Tek explains the raison d'être for the P6230/P6231 thus:
The P6230 acts as a standard 500 Ω passive voltage probe with the additional capability of having an adjustable tip "nulling voltage." This feature reduces the dc-loading effects on the probe when it is used to measure signals whose mid-voltage value is other than zero volts, or in circuits where the termination impedance is returned to other than ground level. The Input Bias/Offset Voltage may be adjusted so that at a particular test-signal voltage both ends of the probe input-resistor are at equal potentials and no current is flowing through the resistor.
ECL logic is most commonly operated from a −5.2 V supply with VCC connected to ground. The output of an ECL gate is the emitter of an NPN emitter follower stage. The output is pulled down to a negative supply (about −2 V) with an external resistor (50 Ω to 100 Ω). Since speed is a major consideration in ECL designs, the interconnections between gates are often transmission lines, and the pull-down resistor doubles as a line termination.
If a standard 500 Ω, 10× probe without the input Bias/Offset feature were used to examine an ECL output, the probe's 500 Ω resistance to ground would form a voltage divider with the gate's output-termination resistor. This divider can cause distortion of the output signal levels, shift the DC operation point of the output transistor, and reduce the gate's noise margin.
The DC-load nulling capability of the P6230 helps to solve this problem. By adjusting the Input Bias/Offset Voltage to the ECL low level or to the termination voltage, the only effect of the probe resistance will be a small decrease in the ECL output-termination resistance. The effect of the probe on output voltage levels is negligible.
Links
Prices
| Year | 1984 | 1987 | 1989 | 1991 | 1995 |
|---|---|---|---|---|---|
| P6230 Catalog price | $385 | $395 | $420 | $525 | – |
| In 2023 Dollars | $1,100 | $1,100 | $1,000 | $1,200 | – |
| P6231 Catalog price | – | $410 | $410 | $525 | $799 |
| In 2023 Dollars | – | $1,200 | $1,000 | $1,200 | $1,600 |
Pictures
-
P6230 compensation box
-
P6230 Switchable terminator
-
P6230 Compensation box interior
-
P6230 Compensation box interior
-
P6231
-
P6230 probe tip with alligator clip ground lead
-
-
Probe tip components
-
Low-inductance ground lead
-
-
-
Probe-to-PCB adapters
-
Probe-to-PCB adapters
-
P6230 circuit diagram
-
P6230 input impedance graph
Measurements
-
-
P6230 Rise time without ground lead: 9.2 * 20 ps = 184 ps (equiv. to 1.9 GHz bandwidth)
-
Effect of using the "low inductance" ground lead - rise time 400 ps, bandwidth 875 MHz
-
Using the 250 mm (9.8") alligator ground lead - severe pulse distortion, rise time ~3 ns (115 MHz)!
-
Bandwidth vs. grounding, from manual
