PMK FF-WSQ-2500V High Voltage Optically Isolated Probe Instruction Manual

Probing Solutions.
Made in Germany.
FireFly®
High Voltage Optically-Isolated Probe
with Universal BNC Interface

1.5 GHz, >180dB CMRR
Preliminary
Instruction Manual
Copyright © 2024 PMK – All rights reserved.

Manufacturer

PMK Mess- und Kommunikationstechnik GmbH
Königsteiner Str. 98
65812 Bad Soden, Germany
Tel: +49 (0) 6196 999 5000
Internet: www.pmk.de
E-Mail: sales@pmk.de

Warranty

PMK warrants this product for normal use and operation within specifications for a period of one year from date of shipment and will repair or replace any defective product, which was not damaged by negligence, misuse, improper installation, accident or unauthorized repair or modification by the buyer. This warranty is applicable only to defects due to material or workmanship. PMK disclaims any other implied warranties of merchantability or fitness for a particular purpose. PMK will not be liable for any indirect, special, incidental, or consequential damages (including damages for loss of profits, loss of business, loss of use or data, interruption of business and the like), even if PMK has been advised of the possibility of such damages arising from any defect or error in this manual or product.

Compliance Information

The FireFly® probing system complies with the following relevant union harmonization legislation, safety and environmental standards. Only professionals and qualified personnel should use this product.
Serious injury or death may occur as result of incorrect usage of this product.

Probe

• IEC/EN 61010-1:2010 – Safety Requirements for Electrical Equipment for Measurement, Control and Laboratory Use, Part 1: General Requirements
• IEC/EN 60825–1 – Safety of Laser Products Part 1: Equipment Classification and Requirements -Edition 3 (2014)
• US 21CFR Part 1010 – Performance Standards for Electronic Products: General
• US 21CFR Part 1040 – Performance Standards for Light- Emitting Products
• Laser Certification: Class 1 Laser Product

This product complies with 21 CFR 1040.10 and 1040.11 except for deviations pursuant to Laser Notice No. 50, dated June 24, 2007.
CAUTION. Use of controls or adjustments for performance of procedures other than those specified herein may result in hazardous exposure.

Battery
Do not use any other batteries than recommended by PMK.
Only use chargers that are suitable for Li-Ion batteries.

• EU model
  Manufacturer: Ansmann AG, Industriestr. 10, 97959 Assamstadt, Germany
  Model: 18650 protected Lithium-Ion rechargeable battery, 3.6V, typ. 3400mAh, safety board inside, inclusive micro-USB charging input connector, CE and UKCA conform.
  The battery switches off at approx. 2.5V to protect the battery against deep discharge.
  Charging the battery afterwards only works with the appropriate Ansmann USB charger. If you use an external charger this will not work as the safety circuit of the battery does not allow this.

• US model
  Manufacturer: Tenergy, 436 Kato Terrace, Fremont, CA 94539 U.S.A.
  Model: 30016-04, 18650 protected Lithium-Ion rechargeable battery, 3.7V, 2600mAh, UL1642 certified.
  The battery switches off at approx. 2.75V to protect the battery against deep discharge.

• Asian model
  Manufacturer: Quantum Lighting Products Limited, Flat A, 13/F, Efficiency House, 35 Tai Yau Street, San Po Kong, Kowloon, Hong Kong
  Model: LG 18650 protected Lithium-Ion rechargeable battery, 3.6V, 3400mAh, TYPE C charging input connector, IEC62133, PSE conform.
  The battery switches off at approx. 2.5V to protect the battery against deep discharge.

IEC Pollution Degrees

Definitions and Examples:

Overview of measurement categories according to IEC 61010-01
O = No Measurement Category (Other circuits that are not directly connected to mains)

Pollution Degree 1
No POLLUTION or only dry, non conductive POLLUTION. NOTE: The POLLUTION has no influence.
Pollution Degree 2
Only- non conductive POLLUTION. Occasionally, however, a temporary conductivity caused by condensation must be accepted.
Pollution Degree 3
Conductive POLLUTION occurs or dry, non-conductive POLLUTION occurs which becomes conductive due to condensation which is to be expected.

IEC Safety Symbols

The following symbols may appear on the product or in this instruction manual:

| Caution, risk of danger. Refer to manual.
---|---
| Caution, risk of electric shock.
| Earth (ground) TERMINAL.

Safety and Handling Information

The probe head, tip cables and accessories are NOT for hand-held use. The overall safety of any measurement setup incorporating this probe is the responsibility of the user.
The probe head is optically isolated and galvanically isolated from the measuring system and earth ground.
To avoid personal injury and to prevent fire or damage to this product or products connected to it, review and comply with the following safety precautions. Be aware that if you use this probe assembly in a manner not specified the protection this product provides may be impaired. Only qualified personnel should use this probe assembly.
Beware of High Voltages.
Observe probe and probe accessory ratings. Do not apply any electrical potential to the probe input, which exceeds the maximum ratings of the probe head, tip cables or the accessories connected to it. In a combination, the lower rating / measurement category applies to both the probe and accessories connected to it. Make sure to comply with the voltage versus frequency derating curve.
Do not connect the probe head/tip cable to an energized circuit to avoid the risk of shock. Always de-energize the circuit-under-test before installing or removing the probe head or tip cable from the circuit-under-test. The plastic case of the probe head and insulating sleeve on the tip cable do not supply adequate isolation
Keep away from hazardous live circuits.
Avoid open circuitry. Do not touch connections or components when power is present.
Maintain safe clearance from the Probe Head and Tip Cable while connected to the energized circuit
Avoid unnecessary stress. Do not overbend the fiber cable or probe tip cable.
The small electrical components of the probe are sensitive to shock and impact. Avoid any unnecessary stress to the probe like throwing, falling and strong vibrations.
The FireFly® fiber cable between the probe head and the interface box contains multiple optical fibers. Avoid tight radius bends, crushing, crimping, twisting, or otherwise stressing of the fiber cable. Do not crush, crimp, twist, pull, jerk or sharply bend the fiber-optic cable. Avoid making loops in the fiber-optic cable smaller than 12.7cm (5in).
Avoid over-bending the Probe Head’s Tip Cables; do not exceed the minimum bend radius of 5cm (2in).
Keep products clean and dry.
Remove all connections of the probe before cleaning. Keep the fiber cable clean and free from contaminants in order to maintain the 60kV common mode voltage rating.
Inspect the fiber cable for dirt, contaminants or damage before each use and clean using a dry, lint-free cloth. If dirt remains, use a soft cloth or swab dampened with a 75% isopropyl alcohol solution and rinse with deionized water. A swab is useful for cleaning narrow spaces, use only enough solution to dampen the swab or cloth. Do not use abrasive compounds on any part of the probe.
Do not use chemical cleaning agents; they may damage the probe. Avoid using chemicals that contain benzine, benzene, toluene, xylene, acetone, or similar solvents.
Do not operate with suspected failures.
Refer to qualified service personnel.
Do not operate in wet or damp conditions.
Condensation may occur if a unit is moved from a cold to a warm environment.
Do not operate the product in an explosive atmosphere.
Connect and disconnect properly.
The circuit-under-test MUST BE DE-ENERGIZED (TURNED OFF) when handling, connecting & disconnecting the probe head, tip cables or accessories to the circuit.
Use ONLY non-conductive probe head & tip holders.
Use only PMK recommended 18650 batteries in the probe head.
Avoid applying an input signal without batteries in the probe head.
Use only the originally provided carry case to store or transport the probe not in use.
If the probe is no longer being used, and before the probe is placed back into the probe case, remove the battery from the probe head for storage.
**** When mounting the probe in a positioner, do not overtighten the thread of the insulating plastic probe holder.

Lithium-Ion 18650 Battery Charging and Storage Information
For optimal charging, the ambient temperature during charging should be 24±2.5°C. Batteries should be stored in a dry, room temperature space. Avoid any situations that might subject the batteries to either extreme cold or heat. Between the range of -20°C to +50°C (-4°F to +122°F) is sufficient but the most optimal storage temperature is somewhere around 77°F or 25°C.
Before handling the probe head to change the battery, make sure the circuit under test has been de-energized or has been disconnected from the circuit-under-test.
Use ONLY the PMK recommended 18650 batteries, in the probe head. If using a battery with a built in USB charge port, connect the appropriate USB cable and connect to a USB port on the oscilloscope, AC power adaptor or PC. Use only the PMK recommended charger.
Charging times will vary based on the battery and the charger used.
Observe battery safety: The FireFly® probe head is powered by a user- replaceable 18650 rechargeable Lithium-Ion battery.
To avoid personal injury or property damage due to electrical burst, smoke, fire or explosions, please operate the probe within the specified operating conditions.
Do not drop the probe or subject it to strong impacts.
Do not use the probe if it has been damaged in any way.

Clearance Requirements
The probing system can be used for very high common mode voltages. Observe all pre-cautions andinformation from the manual when using this product. See also the specifications and referring deratingcurves in this manual.
**** Maintain at least 1m (40in) safe clearance of the probe head, tip cable and tip cable accessories in all directions when connected to an energized circuit.

RF burn hazard zone around the probe head and tip cable

Maximum Safe Handling Limits
Common Mode Voltage (Probe Head to Earth Ground)

About FireFly®

The FireFly® high voltage optically isolated probe offers industry leading performance that combines the ability to accurately resolve high bandwidth, small differential signals in the presence of large common mode voltages with its ultra-high common mode rejection performance across its entire bandwidth. With >1.5GHz bandwidth, wide differential input  range, unmatched common mode rejection ratio CMRR up to >180dB (1 billion to 1 rejection), and a 60kV common mode, FireFly® is the ideal measurement solution for both GaN and SiC device characterization and system level design development.
PMK‘s optically isolated interface and unique compact angled probe head design are the key attributes that set FireFly® apart from the other solutions in the market, providing very stable and accurate measurements over a wide temperature range and easy access to the measurement points in tight spaces.
The compact angled probe head design allows for shorter tip cables to be used, resulting in higher signal fidelity measurements and reduced stresses placed on the measurement test  point. FireFly®‘s wide selection of probe tip connections and accessories offer reliable, hands-free, high-fidelity connectivity to the measurement points. Using industry standard MMCX and square pins connections allow FireFly® to easily interface to test boards that have already been design with these test points.
The FireFly® probe head is powered by an easy to change, rechargeable, industry standard 18650 battery that provides continuous operation for up to 30h at room temperature. FireFly® has a universal BNC output connector and is compatible with any oscilloscope with a 50Ω input impedance or 1MΩ input impedance and a 50Ω feed-through termination, allowing FireFly® to be used on any oscilloscope in the lab. For accurate deskew, each probe‘s unique propagation delay is measured and added to each probe label.

Coming soon: FireFly® series will have the capability to be controlled from either remote control or the controls located on the interface box. The „PMK Probe Control“ software  provides the ability for the user to control the probe remotely via a computer, and provides the user with a graphical user interface. The software is free of charge, and included with PMK’s 2ch and 4ch power supplies PS2 and PS3, which are required to power the probe. The PS2 and PS3 power supplies all have a USB interface and are available with optional LAN interface. The new AP-01, 1 channel battery pack power supply, provides > 8h of portable and isolated operation, which allows the user the flexibility of where the probe can be used. The AP-01 supplies power only to the probe with no software remote control.

Factory Calibration

Annual re-calibration is recommended. ISO17025 calibration upon delivery or as re-calibration is possible on request.

Specifications

Read the Instruction Manual before first use, and keep it for future reference. A digital copy of the latest Instruction Manual revision can be downloaded at www.pmk.de
Specifications that are marked with * are guaranteed, others are typical. Do not exceed specifications. Allow the probe to warm up for 20 minutes. The probe head and tip cables are not for handheld use. The probe can be used without the probe tip. To achieve the most accurate measurement results, review the “Getting Started” section in the Instruction Manual. This probe comes with 1 year warranty.

Electrical Specifications
Observe adequate spacing between probe head components and earth ground. This product is not rated for CAT II, III or IV. Do not exceed the specifications. Use original PMK power supplies only.

FireFly®| Bandwidth
(-3dB)| Rise time
(10% – 90%)| Input
Attenuation| Input Impedance2
---|---|---|---|---
SMA Input| > 1.5 GHz| <250 ps|   1X| 200 kΩ || 4.0 pF
FF-MMCX-1V| > 1.5 GHz| <250 ps|   1X| 50 Ω 3
FF-MMCX-10V| > 1.3 GHz| <280 ps| 10X| 2 MΩ || 3.4 pF
FF-MMCX-25V| > 1.3 GHz| <280 ps| 25X| 4.9 MΩ || 2.1 pF
FF-MMCX-50V| > 1.3 GHz| <280 ps| 50X| 10 MΩ || 2 pF
FF-MMCX-250V| > 1.3 GHz| <280 ps| 250X| 20 MΩ || 2.1 pF
FF-WSQ-500V| > 1.5 GHz| <250 ps| 500X| 40 MΩ || 2.9 pF
FF-WSQ-1000V| > 1.5 GHz| <250 ps| 1000X| 40 MΩ || 2.9 pF
FF-WSQ-1500V| > 1.5 GHz| <250 ps| 1500X| 40 MΩ || 2.9 pF
FF-WSQ-2500V| > 1.5 GHz| <250 ps| 2500X| 40 MΩ || 2.9 pF

Maximum Rated Input Voltages4

Common Mode Voltage5
(Maximum Voltage to Earth)| ± 60 kV (DC + Peak AC)
---|---
No Measurement Category| Linear Input
Voltage Range
(DC + Peak AC)2| Maximum Non-Destruct Differential
Input Voltage
(DC + Peak AC)2
SMA Input| ± 1 V|     5 V
FF-MMCX-1V| ± 1 V|     5 V
FF-MMCX-10V| ±10 V|   50 V
FF-MMCX-25V| ± 25 V| 100 V
FF-MMCX-50V| ± 50 V| 100 V
FF-MMCX-250V| ± 250 V| 300 V
FF-WSQ-500V| ± 500 V|     300 V
FF-WSQ-1000V| ± 1000 V|   3000 V
FF-WSQ-1500V| ± 1500 V|   3000 V
FF-WSQ-2500V| ± 2500 V|   3000 V
Pollution Degree| 2

Electrical Specifications

Common Mode Rejection Ratio**| DC| 1 MHz| 100 MHz| 200 MHz| 500 MHz| 1 GHz
---|---|---|---|---|---|---
SMA Input| > 180 dB| 165 dB| 110 dB| 100 dB| 90 dB| 90 dB
FF-MMCX-1V| > 180 dB| 145 dB| 95 dB| 85 dB| 90 dB| 90 dB
FF-MMCX-10V| > 180 dB| 145 dB| 85 dB| 82 dB| 80 dB| 65 dB
FF-MMCX-25V| > 180 dB| 142 dB| 78 dB| 75 dB| 76 dB| 58 dB
FF-MMCX-50V| > 180 dB| 135 dB| 75 dB| 70 dB| 70 dB| 50 dB
FF-MMCX-250V| > 180 dB| TBD| TBD| TBD| TBD| TBD
FF-WSQ-500V| > 180 dB| TBD| TBD| TBD| TBD| TBD
FF-WSQ-1000V| > 180 dB| TBD| TBD| TBD| TBD| TBD
FF-WSQ-1500V| > 180 dB| TBD| TBD| TBD| TBD| TBD
FF-WSQ-2500V| > 180 dB| TBD| TBD| TBD| TBD| TBD
DC Gain Accuracy| < 2 %± DC Offset voltage “
Noise (input referred)| SMA Input (1X): < 2 mV rms
With tip cable: (SMA Input noise) – (Tip cable input attenuation) scales proportionally to tip attenuation
DC Offset Voltage (input referred)| SMA Input (1X): < 1.5 mV (After Auto-Zero)
With tip cable: (SMA Input offset voltage) • (Tip cable input attenuation) 8 scales proportionally to tip attenuation
Propagation Delay| 2 m fiber cable: 15 ns
The probe specific value is measured and printed on interface box label, tip cable approx. 500 ps
Battery Life| > 30 h © 22 °C — 25 °C, > 20 h © 0 °C, >4 h © 50 °C
Dependent on probe head operating temperature (Continuous Operation)
Output Termination & Coupling| 50Ω DC
Battery Type| Protected 18650 Li-Ion, Rechargeable, 3.7V Certified
Laser Certification| Laser Class 1
IEC/EN 60825-1:2014, US 21CFR Part 1010, US 21CFR Part 1040

Notes:

• Guaranteed specification
  ** Preliminary specification

  1. Determined when using a PS-02 power supply at +23°C ambient temperature.
  2. For input voltage and input impedance derating graphs review the FireFly® instruction manual.
  3. Terminated, 50 Ω transmission line.
  4. As defined in IEC 61010-1. Rated for indoor, dry location use only.
  5. Galvanically isolated FireFly® probe head through fiber optic connection.
  6. CMRR performance is >180dB below 500kHz. See CMRR graph.
  7. Example: 10x tip FF-MMCX-10V noise = 10x SMA input noise.
  8. Example: 10x tip FF-MMCX-10V offset = 10x SMA input offset.

Environmental Specifications

humidity) at up to +40 °C, 5 % to 45 % RH above +40 °C up to
+50 °C, non-condensing
Interface Box| 5 % to 85 % RH (relative humidity) at up to +40 °C, noncondensing
Non-Operating| Tip Cables & Adapters| 5% to 85% RH (relative humidity) at up to +85 °C, noncondensing
Probe Head & Interface Box| 5 % to 85 % RH (relative humidity) at up to +40° C, 5 % to 45 % RH above +40° C up to
+71° C, non-condensing
Maximum Altitude| Operating| | 3000 m (9843 ft)
Non-Operating| | 15000 m (49213 ft)

Physical Specifications

Output: BNC (Male) – Interface Box

Dimensions
The dimensions shown are in mm. Drawings from the probe tips are coming soon. If the needed drawing is missing, please contact us via sales@pmk.de

Typical Common Mode Rejection Ratio (CMRR)

Typical Maximum Differential Input Voltage (CW)
Note that the maximum input voltage rating of the probe decreases as the frequency of the applied signal increases.
The maximum input voltage derating is coming soon.

Typical Frequency Response

Typical Pulse Response
The graphs are normalized to 1 for better comparison.

Typical Differential Input Impedance
Note that the maximum input voltage rating of the probe decreases as the frequency of the applied signal increases.

User Interface

Interface Box Controls & Indicators

Probe Status Indicator

Probe Head
Power ON| Successful powered up and probe head is on and warmed up. Ready for measurements.
| Green
(Blinking)| Probe Head
Warm Up| Probe head has successfully powered up and warming up Probe head not ready. Do not energize your circuit under test.
| Red
(Blinking)| Probe Head
OFF — Empty
Battery| Caution — Empty or missing battery. Probe Head is powered OFF and not able to pass a signal. Probe head not ready.
| Yellow
(Solid)| Probe Head
Power OFF| Caution – Probe Head is powered OFF and not able to pass a signal. Probe head not ready.
| Blue
(Solid)| Auto Zero In
Process| Auto-Zero is in process – Very fast. Probe head not ready. De- energized circuit under test before performing an Auto-Zero required.
| Red Blue
(Blinking)| Error
Condition| An error condition has occurred – Power cycle the probe & check probe head battery. Probe head not ready. Do not energize your circuit under test. If power cycling not successful, please contact our support.

Probe Head Battery Level Indicators
The Battery Level Indicators will illuminate after the Probe Head is turned on.

the battery is full and One (1) Solid Green LED indicates the battery will soon need to be replaced.
| Bottom Orange
(Solid)| Low Battery
(Warning)| Battery replacement recommended.
| Bottom Red
(Blinking)| Low Battery
(Critical)| Warning – Battery needs to be changed.
| All OFF| Empty or NO Battery
Installed| Action required: Probe Head is NO longer in operation and passing a signal
– De-energize your circuit
– Check and replace battery

Probe Head Power ON/OFF Button
Turn the probe head ON before use and power OFF after use to conserve the battery. The Interface
Box will power up even if the probe head is in the Probe Head OFF mode. See Probe Status Indicator Information.
When the Probe Head is in the OFF mode, the probe will not pass a signal.

Auto-Zero Button
Press the Auto-Zero Button on the probe interface box to remove any DC offset errors (drift) in the probe’s output. See Probe Status Indicator overview for more information.
Make sure the circuit-under-test is de-energized. No signal must be applied to probe tip.

Remote Interface

COMING SOON: The “PMK Probe Control“ software, available free of charge, provides the ability for the user to control the probe remotely via a computer, and provides the user with a graphical user interface. Download: www.pmk.de/probecontrol
In order to achieve the highest CMRR and minimum CM loading, keep the probe head away from surrounding metal or earth ground.

Getting Started

Read the Safety and Handling Information, the Specifications and the entire Instruction Manual before first use, and keep them for future reference. A digital copy of the latest  revision can be downloaded at www.pmk.de

Cable Selection
Each tip cable has a set of labels on them that specify the linear input voltage range as well as the attenuation factor to correctly setup the scale factor on the oscilloscope to display the correct signal amplitudes. When selecting a tip cable for the measurement being made, consider the following criteria:

1. Maximum DC + AC peak voltage at the test point to be measured
2. Minimum differential loading (input resistance and capacitance) that test circuit can tolerate
3. Minimum needed sensitivity for the measurement (minimum V/div setting)

Probe Setup

1. Connect the FireFly® Interface Box to the BNC input of the oscilloscope or other measurement system with either an internal or external 50Ω input termination. If using a tip cable, attach the tip cable to the probe head SMA connector by turning it clockwise until fully tightened, so the tip cable is secure and not loosen up when in use. Set the  propagation delay on the oscilloscope to the measured propagation value printed on the FireFly® Interface Box’s label and add the tip cable/accessory delay if one is used. Set  the oscilloscope’s attenuation scale factor to the tip cable’s attenuation.

2. Connect the PMK Power Supply, model 2ch PS2, 4ch PS3 or battery pack AP-01, to the power connector on the FireFly® Interface Box using a PMK Probe Connection Cable. Turn on the Power Supply. The Interface Box Probe Status Indicator turns red and the Probe Head Battery Level Indicators will light to indicate the probe head’s battery level.
   The power supply pin assignment is different from other power supplies. Use only original PMK power supplies with PMK probes.
   Probe’s power supply pin assignment “cable view”
   Before handling the probe head, tip cable or tip cable accessories, make sure the circuit-under-test is either de-energized or not connected to the probe.

3. Insert or Replace the Battery
   Open the probe head’s battery compartment by unscrewing the battery cap counter-clockwise. Insert or replace the existing battery with a fully charged 18650 rechargeable battery, in order to achieve the longest probe head operating time. Follow the polarity markings on the compartment.
   Make sure that the positive end of the battery goes in first and the negative end of the battery is facing out, towards the battery cap. Close the probe head’s battery compartment by screwing the battery cap back onto the probe head in the clockwise direction and tighten.

4. Power ON/OFF the Probe Head
   Press the Probe Head Power ON/OFF Button to turn on the probe head. Battery indicators will only illuminate when the Probe Head Power is turned ON and will turn off when Probe Head Power is turned OFF. Wait for the Probe Status Indicator on the interface box to turn green, which means the probe is now ready to make a measurement.

5. Connect the insulating Probe Holder
   Insert the probe with its holder straight from the top into the probe holder. Connect the probe head to the FireFly probe holder by aligning the attachment interface and then rotating it 90° to securely lock the probe head and holder together.
    Before twisting the probe in the holding system, make sure the probe is inserted fully straight from the top.
   If the 10kV insulating probe holder FF-HAL-10kV is used, screw the M6 thread to the PMK positioning system before connecting the FireFly® probe to the positioner.
   Make sure not to overtighten the plastic thread.
   If another probe holder is being used, use non-conducting probe holders only.

6. Attach the Probe Tip Cable or accessory input connector to the circuit-under-test. When using an MMCX connector, insert the tip cable’s MMCX plug straight into the mating socket until a “click” sound occurs to indicate a proper connection between the plug and socket.
   Observe a disengagement force of <8N for longest MMCX connector lifetime.
   When removing the tip cable from the MMCX socket, grasp the tip cable’s MMCX connector and pull straight out, taking care not to wiggling the connector side-to-side to prevent excessive stresses on the socket and its connection to the DUT.

7. Auto-Zero Button
   Press the Auto-Zero button on the interface box to remove any DC offset errors (drift) in the probe’s output.
   Perform Auto-Zero after each tip cable change.

8. Ready for making the measurements: Apply power to the circuit-under-test to begin making the measurements. To achieve the most stable measurements, allow the probe to warm up 20 minutes.

Connection to the Test Points (Circuit-Under-Test)
To achieve the best performance from the FireFly® probe, use an MMCX connector as close to the test point as possible. The MMCX connectors provide a compact footprint and solid metal body that provide the best signal fidelity of the signal being measured as well as shielding down as close as possible to the test point. This connection also provides a stable and repeatable measurement.
To achieve the best electrical performance, especially the CMRR performance and EMI susceptibility, place the probe tip adapter/accessories as close as possible to the circuit board.
To minimize the effects of common mode capacitive loading of the probe head/tip cable and maximum CMR, consider the following items.

• Whenever possible, connect the coaxial (common) shield of the tip cable to the test point that has the least dynamic signal, with respect to earth ground, relative to the tip cable  signal (center) test point in the circuit-under-test.
• The coaxial (common) shield of the tip cable and tip cable adapters should always be connected to the lowest impedance point (usually a circuit common or power supply rail) in the circuit-undertest (relative to the tip cable/center conductor) to obtain the most accurate waveform.
• Increasing the physical distance between the probe head/tip cable and any conductive surface will reduce the parasitic capacitance.

Making the Measurement
Tips for making the highest signal fidelity measurements:

• To achieve the best CMRR performance, make sure to tighten the tip cable to probe SMA connection.
• Measure as close as possible to the desired measurement point.
• Avoid fiber movement when making a precise measurement.
• If use a tip cable adapter/accessory with input leads, twist the input leads together to reduce the input inductance and improve the CMRR of the test setup.
• Add external ferrite beads over the tip cable or adapter/accessory as close as possible to the test points will improve the CMRR and common mode loading on the circuit-under-test.

Scope of Delivery

Not all required items are included in the scope of delivery of the base probe FireFly FF-1500. See Ordering Information to configure your individual probing solution and select a required PMK power supply. The following accessories are included in the scope of delivery.

• FireFly® FF-1500 base Probe, ±1V input range
• 2x 18650 rechargeable Lithium Ion batteries
• USB Wall charger + USB cable (for battery charging) Charger type may vary by region
• Interface box probe connection cable (0.5m), 890-520-900
• Probe head holder 2-Footer (Bi-Pod), FF-2FOOTER
• Set cable coding rings (3×4 colors)
• Instruction Manual

The accessories for this probe series have been safety tested.
Do not use any other accessories, batteries or power supplies than what is recommended.

Ordering Information

Step 1: Select Base Probe

FF-1500
FireFly® optical isolated probe, 1.5GHz, >180dB, 2m fiber cable (2 batteries and 2footer included, required power supply to be ordered separately)

Step 2: Select Probe Tip Cables
The probe tip cables are interchangeable without requiring any tools. The probe head SMA input range is ±1V with no attenuation.

FF-MMCX-1V| FireFly® probe tip cable, MMCX,  ±1V, >1.5GHz,  1x attenuation, 50Ω terminated for shunt measurements
---|---
FF-MMCX-10V| FireFly® probe tip cable, MMCX, ±10V, >1.3GHz, 10x attenuation
FF-MMCX-25V| FireFly® probe tip cable, MMCX, ±25V, >1.3GHz, 25x attenuation
FF-MMCX-50V| FireFly® probe tip cable, MMCX, ±50V, >1.3GHz, 50x attenuation
FF-MMCX-250V| FireFly® probe tip cable, MMCX, ±250V, >1.3GHz, 250x attenuation
FF-WSQ-500V| FireFly® probe tip cable for 5.08mm square pins, ±500V, >1.5GHz, 500x attenuation
FF-WSQ-1000V| FireFly® probe tip cable for 5.08mm square pins, ±1kV, >1.5GHz, 1000x attenuation
FF-WSQ-1500V| FireFly® probe tip cable for 5.08mm square pins, ±1.5kV,

1.5GHz, 1500x attenuation
FF-WSQ-2500V| FireFly® probe tip cable for 5.08mm square pins, ±2.5kV, 1.5GHz, 2500x attenuation

Step 3: Select Connectivity Accessories
Observe the frequency derating of each accessory. Observe maximum input voltage of the probe’s input. Do not use any other accessories.

FF-SQ-MMCX5
5x MMCX to 2x 0.025” (0.635mm) socket , -40°C to +125°C|
---|---
FF-HTSPAD-MMCX3
3x MMCX solder-in cable adapter HT, 50Ω RF micro coax to flex solder-in pad, -40°C to +155°C (green = 0Ω, yellow = 36Ω, red = 75Ω)|
FF-HTS-MMCX2
2x MMCX solder-in cable adapter HT, MMCX socket with 50Ω RF micro coax cable and open end, -40°C to +155°C|
FF-UFL-MMCX2
2x MMCX cable adapter, MMCX socket with 50Ω RF micro coax cable to UF.L plug, -40°C to +125°C|
FF-2XR-MMCX
MMCX to 2x XR Mini-Hook|
972416100
2-pole test clip SMD for use with FF-SQ-MMCX5|
P25-2
Pico Hook™ red for use with FF-SQ-MMCX5|
P25-0
Pico Hook™ black for use with FF-SQ-MMCX5|
D010031
50Ω BNC feed-through for 1MΩ input oscilloscopes|

Step 4: Select Positioning System

FF-3DPOS200
3D positioner with steel base, 200 mm span width and FireFly® probe lder, max 10kV|
---|---
FF-HAL10kV-3
FireFly® probe holder, max 10kV for use with PMK’s 3D Probe  Positioning Systems and SKID Probes and PCB Board holder systems, no stand-alone use|
FF-2FOOTER
Probe positioner 2-Footer (Bipod), included in probe’s scope of delivery|

Step 5: Select Power Supply
A PMK power supply PS2 or PS3 is required for using the probe.
The power supply pin assignment is different from other power supplies. Use only original PMK power supplies with PMK probes.

control)
889-09V-PS3| PS-03 (4 channels, with USB interface for remote control)
889-09V-PS3-L| PS-03-L (4 channels, with LAN and USB interface for remote control)
889-09V-AP01| AP-01 (battery pack, 1 channel, no remote control)
890-520-900| Power supply cable (0.5 m), included in probe’s scope of delivery
890-520-915| Power supply cable (1.5 m)

Observe Connector Pin-Out for PMK power supply cables

Step 6: Select Accredited Calibration
KAL-DAKKS-FF ISO 17025 (re-)calibration
Step 7: Select Additional Accessories
D010031 50Ω BNC feedthrough for use with 1MΩ oscilloscope inputs, 0.5W

Coming Soon / In Development
New connectivity solutions
Power-Over-Fiber adapter
If you need any non-published accessory, please contact us via sales@pmk.de

Notes

Copyright © 2024 PMK – All rights reserved.
Information in this publication supersedes that in all previously published material.
Specifications are subject to change without notice.
M-FF-1500
Revision 06, 2024

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