Teledyne HVD3000, HVD3000A, HVD3106, HVD3106A, HVD3106-6M Operating Manual

Operator’s Manual

HVD3000 / HVD3000A
High

-Voltage

Differential Probes

HVD3000 / HVD3000A

High-Voltage Differential Probes

Operator's Manual

November, 2018

HVD3000 / HVD3000A High-Voltage Differential Probes Operator's Manual

© 2018 Teledyne LeCroy, Inc. All rights reserved.

Unauthorized duplication of Teledyne LeCroy documentation materials other than for internal
sales and distribution purposes is strictly prohibited. However, clients are encouraged to
duplicate and distribute Teledyne LeCroy documentation for their own internal educational
purposes.

Teledyne LeCroy is a trademark of Teledyne LeCroy, Inc. Other product or brand names are
trademarks or requested trademarks of their respective holders. Information in this publication
supersedes all earlier versions. Specifications are subject to change without notice.

930490-00 Rev A
November, 2018

Operator’s Manual

i

Contents

Introduction .................................................................................................................................... 1

Safety .............................................................................................................................................. 3

Voltage Derating for Accessories ................................................................................................. 5

HVD310x and HVD310xA Probes .................................................................................................. 6

HVD3206 and HVD3206A Probes ............................................................................................... 13

HVD3605 and HVD3605A Probes ............................................................................................... 18

Functional Test Procedure .......................................................................................................... 22

Performance Verification Procedure .......................................................................................... 23

Required Equipment ................................................................................................................. 23

Preliminary Procedure.............................................................................................................. 24

Certification Procedure ............................................................................................................ 24

Checking Probe Attenuation in XStreamBrowser ................................................................. 26

HVD3000 / HVD3000A Test Record ........................................................................................ 27

Operation ...................................................................................................................................... 28

Connecting to the Test Instrument ......................................................................................... 28

Connecting to the Test Circuit ................................................................................................. 28

Operating with an Oscilloscope .............................................................................................. 29

Maintenance ................................................................................................................................. 33

Cleaning .................................................................................................................................... 33

Calibration Interval ................................................................................................................... 33

Service Strategy ....................................................................................................................... 33

Replacement Parts ................................................................................................................... 33

Returning a Product for Service .............................................................................................. 34

Technical Support .................................................................................................................... 35

Reference ...................................................................................................................................... 36

Certifications ................................................................................................................................ 39

HVD3000 / HVD3000A High-Voltage Differential Probes

ii

Warranty

THE WARRANTY BELOW REPLACES ALL OTHER WARRANTIES, EXPRESSED OR IMPLIED,
INCLUDING BUT NOT LIMITED TO ANY IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS, OR
ADEQUACY FOR ANY PARTICULAR PURPOSE OR USE. TELEDYNE LECROY SHALL NOT BE LIABLE
FOR ANY SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES, WHETHER IN CONTRACT OR
OTHERWISE. THE CUSTOMER IS RESPONSIBLE FOR THE TRANSPORTATION AND INSURANCE
CHARGES FOR THE RETURN OF PRODUCTS TO THE SERVICE FACILITY. TELEDYNE LECROY WILL
RETURN ALL PRODUCTS UNDER WARRANTY WITH TRANSPORT PREPAID.

The product is warranted for normal use and operation, within specifications, for a period of
one year from shipment. Teledyne LeCroy will either repair or, at our option, replace any
product returned to one of our authorized service centers within this period. However, in
order to do this we must first examine the product and find that it is defective due to
workmanship or materials and not due to misuse, neglect, accident, or abnormal conditions
or operation.

Teledyne LeCroy shall not be responsible for any defect, damage, or failure caused by any
of the following: a) attempted repairs or installations by personnel other than Teledyne
LeCroy representatives, b) improper connection to incompatible equipment, or c) use of
non-Teledyne LeCroy supplies. Furthermore, Teledyne LeCroy shall not be obligated to
service a product that has been modified or integrated where the modification or
integration increases the task duration or difficulty of servicing the product. Spare and
replacement parts and repairs all have a 90-day warranty.

Products not made by Teledyne LeCroy are covered solely by the warranty of the original
equipment manufacturer.

Operator’s Manual

1

Introduction

The HVD3000 and HVD3000A high-voltage active differential probes are safe, easy-to-use,
and ideally suited for power electronics applications where the reference potential is
elevated from ground. The probes feature:

• Differential voltage measurement capability in high common-mode environments
(up to 6kVrms)

• Exceptional common-mode rejection ratio (CMRR) across a broad frequency range

• Wide differential voltage range

• High offset voltage capability

• 1% DC and low frequency gain accuracy

• AC or DC coupling

• ProBus interface with automatic scaling

• Auto Zero capabilities

The CMRR for the probes is exceptional out to very high frequencies. This greatly assists in
measuring signals in the noisy, high common-mode environments of power electronics.
High CMRR combined with low probe noise and high offset capability makes the probes
capable of measuring very small control signals floating on high common-mode voltages.

The maximum rated differential voltage specifications are provided for using each probe
within a wide differential voltage range. The probes will even display signals above the
maximum rated differential voltage, up to the maximum measurable differential voltage
before saturation limit, although the specifications cannot be guaranteed. Within this range,
the probe is operating below the saturation point of the amplifier, and very reasonable
results can be expected.

Note: HVD3000A probes are fitted with detection circuits that will indicate when the
differential or common mode voltages are beyond the operating ranges of the probe. A
warning will be displayed in the oscilloscope message bar.

The probes are calibrated for high-precision measurements to within 1% at DC to low
frequency (~10 kHz). This provides for high accuracy of top and base voltage levels of
pulse-width modulated signals. The Auto Zero capability permits further measurement
precision by allowing small offset drifts to be calibrated out of the measurement.

HVD3000 / HVD3000A High-Voltage Differential Probes

2

The ProBus interface makes the probe an integral part of the oscilloscope. Power is
provided to the probe through the interface, so there is no need for a separate power supply
or batteries. Attenuation may be either automatically selected based on the oscilloscope
gain range (V/div) setting, with the offset adjust unified with that of the oscilloscope, or
locked to the maximum attenuation setting.

Maximum offset depends on the V/div setting and the oscilloscope model. In general,
Teledyne LeCroy 12-bit High Resolution Oscilloscopes (HRO) and HD4096 High Definition
Oscilloscopes (HDO) provide the most offset capability over the widest range of V/div
settings.

Compatibility

HVD3000 and HVD3000A probes are compatible with most Teledyne LeCroy MAUI
oscilloscopes equipped with the ProBus interface. See the HVD3000 product page on our
website for all compatible oscilloscope models.

Some legacy oscilloscopes, such as WavePro 7000A and WaveSurfer XS, can be made
compatible with HVD3000 probes if upgraded to the Windows XP Professional operating
system and requisite firmware. Contact your regional service center regarding upgrades.

Required Firmware

Proper functioning of the HVD3000 and HVD3000A probes requires a minimum version of
the XStreamDSO™ firmware to be installed on the oscilloscope:

• The HVD310x probes require firmware version 7.4.x.x or greater.

• The HVD3206 and HVD3605 probes require firmware version 7.8.x.x or greater.

• All HVD3xxxA probes require firmware version 8.5.1.0 or greater.

Operator’s Manual

3

Safety

To maintain the probe in a correct and safe condition, observe generally accepted safety
procedures in addition to the precautions specified in this section.

The overall safety of any

system incorporating this product is the responsibility of the assembler of the system.

Symbols

These symbols appear on the probe and accessories or in this manual to alert you to
important safety considerations.

WARNING, HIGH VOLTAGE. Risk of electric shock or burn.

CAUTION of damage to probe or instrument, or WARNING of hazard to health.

Attend to the accompanying information to protect against personal injury or
damage. Do not proceed until conditions are fully understood and met.

ESD CAUTION. Risk of Elecstostatic Discharge (ESD) that can damage the probe or

instrument if anti-static measures are not taken.

Precautions

WARNING. To avoid personal injury or damage due to electric shock or fire:

Do not overload; observe all terminal ratings. Do not apply any potential that exceeds the
maximum rating of the probe and/or the probe accessory, whichever is less.

Comply with the Voltage vs. Frequency derating curve when measuring higher frequency
signals.

Connect and disconnect properly. Always connect the probe input lead to the probe
accessories before connecting to a voltage source. Ensure the connections are secure
before applying voltage. Do not disconnect leads or accessories from a live circuit.

Keep the probe body and output cable away from the circuits being measured. Only
accessory tips are intended for contact with electrical sources.

Use only accessories compatible with the probe. Use only accessories that are rated for the
application. Substituting other accessories than those specified in this manual may create
a shock /burn hazard.

HVD3000 / HVD3000A High-Voltage Differential Probes

4

Keep fingers behind the finger guard of the probe accessories.

Do not remove the probe's casing. Touching exposed connections may result in electric
shock or burn.

CAUTION. To prevent damage to the equipment:

Use only as specified. The probe is intended to be used only with compatible Teledyne
LeCroy instruments. Use of the probe and/or the equipment it is connected to in a manner
other than specified may impair the protection mechanisms.

Do not bend cables excessively.

Use only within the operational environment listed. Do not use in wet or explosive
atmospheres.

Keep product surfaces clean and dry.

Do not operate with suspected failures. Before each use, inspect the probe and accessories
for any damage such as tears or other defects in the probe body, cable jacket, accessories,
etc. If any part is damaged, cease operation immediately and sequester the probe from
inadvertent use.

Operating Environment

Temperature, Operating 0 C to 50 C

Temperature, Non-operating -40 C to 70 C

Relative Humidity, Operating 5% to 80% RH (Non-Condensing)

45% RH above 30 C

Relative Humidity, Non-operating 5% to 95% RH (Non-Condensing)

75% RH above 30 C
45% RH above 40 C

Altitude 3000 m (9842 ft.) max.

Derated to 2000 m (6561 ft.)
when used with clip accessories

Usage Indoors

Operator’s Manual

5

Voltage Derating for Accessories

Accessory Part Number

Derated Max. Input Voltage for
Combined Probe & Accessory

(either input to ground)*

Spade Terminals

PK-HVA-05

1000 V CAT III

Safety Alligator Clips PK-HVA-01 1000 V CAT III

Plunger Alligator Clips PK-HVA-04 1000 V CAT III

Plunger Pincer Clips

PK-HVA-02

1000 V CAT II

Plunger Hook Clips

PK-HVA-03

1000 V CAT II

6kV Alligator Clips PK-HVA-06 6000 V CAT I **

1000 Vrms CAT III

1500 Vdc CAT III

2kV Plunger Alligator Clips PK-HVA-07 2000 V (DC + Peak AC) CAT I **

1000 Vrms CAT III
1500 Vdc CAT III

* See "IEC/EN 61010-031 Definitions" on p.38.
** CAT I per IEC/EN 61010-031/A1:2008. No Rated Measurement Category per IEC/EN 61010-031:2015.

CAUTION. The operating altitude of the probe is derated to 2000 m (6560 ft) when
used with the above accessories.

WARNING. Each accessory has a different measurement (overvoltage) category
(CAT) rating. The voltage and CAT rating of the probe are derated to the values in
the table above when used with the corresponding accessory.

WARNING. While all probes may be used with the HVD310x accessories (spade
terminals, plunger clips, etc.), the voltage and CAT ratings of the probe are derated
to the values in the table above when used with the corresponding accessory.

WARNING. To avoid risk of electric shock or fire, do not exceed either the voltage
rating or category rating. Keep your fingers behind the finger guard of the probe.
Keep the probe body and output cable away from the circuits being measured. Use
only the specified accessories.

HVD3000 / HVD3000A High-Voltage Differential Probes

6

HVD310x and HVD310xA Probes

Probe Kit

The probes are delivered with the following:

Item Description Safety Rating* Part Number QTY

Spade
Terminals
(1)

Designed to connect to terminal
strips, posts and screws, the overall
length is 63 mm (2.48 inches). 4 mm
Banana (female) connector. 1 ea.
red/black.

Insulated 1000 V CAT III PK-HVA-05 2

Safety
Alligator

Clips
(2)

Designed to reliably grip large
components, such as bus bars and
large bolts, the overall length is 92.8
mm (3.65 inches) and the jaw opens
to 32 mm (1.26 inch). Only the lower
jaw is conducive; the top jaw is
insulating plastic. 4 mm Banana
(female) connector.1 ea. red/black.

Insulated 1000 V CAT III PK-HVA-01 2

Operator’s Manual

7

Item Description Safety Rating* Part Number QTY

Plunger
Alligator
Clips
(3)

The clip is designed to securely
grasp thick wires, cables, ground
leads, rails, and screw heads. The
overall length is 153 mm (6.02
inches); the jaw opens to 23 mm
(0.905 inch) max. 4 mm Banana
(female) connector. 1 ea. red/black.

Insulated 1000 V CAT III PK-HVA-04 2

Plunger
Pincer Clips
(4)

Designed with a long, thin, flexible
stem for attaching to hard-to-reach
test points, the entire body is fully
insulated. The overall length is 161.6
mm (6.36 inch). The pincers can
grab leads, pins and wires up to 4
mm (0.157 inch) in diameter. 4 mm
Banana (female) connector. 1 ea.
red/black.

Insulated 1000 V CAT II PK-HVA-02 2

Plunger
Hook Clips
(5)

Designed with a flexible stem to
access deep targets in dense
environments and a 4.5 mm (0.177
inch) hook to attach to wire leaded
parts. The overall length is 157.6
mm (6.20 inches). 4 mm Banana
(female) connector. 1 ea. red/black.

Insulated 1000 V CAT II PK-HVA-03 2

Case

Soft storage case. SAC-01A 1

Foam

Custom foam insert for storage
case.

HVD3106

924228-00

HVD3106-6M
925473-00

1

Operator's
Manual

NA 1

* See "IEC/EN 61010-031 Definitions" on p.38 for measurement category definitions.
‡ See "Replacement Parts" on page 32 for information about ordering replacement accessories.

NOTE: The *-NOACC options offer the probe without the accessories.

WARNING. To avoid injury or death due to electric shock, do not handle probe input
leads connected to the Spade Terminals while they are connected to a live voltage
source. Do not use Spade Terminals as hand-held accessories; they are meant to
be used as a permanent installation in a test set up.

HVD3000 / HVD3000A High-Voltage Differential Probes

8

HVD310x / HVD310xA Specifications

For the current specifications, see the product datasheet at teledynelecroy.com. Below are
some key product specifications.

Specifications are subject to change without notice.

GUARANTEED SPECIFICATIONS

HVD3102

/

HVD3102A

HVD3106

/

HVD3106A

HVD3106

-6M/

HVD3106A

-6M

Bandwidth (probe only)

25

MHz

120 MHz

80 MHz

Risetime 10-90 %

14 ns

2.9 ns

4.4 ns

CMRR Test Limits, 23 C

80 db @ 50 Hz
60 db @ 1 MHz

80 db @ 50 Hz
60 db @ 1 MHz

80 db @ 50 Hz
60 db @ 1 MHz

ELECTRICAL CHARACTERISTICS (ALL PROBES)

Max. Rated Diff. Voltage
(between each input)

1500

V (DC + Peak AC)

Max. Measurable Diff. Voltage
(before saturation)

2000 V (DC

+ Peak AC)

Max. Common Mode Voltage
(

either input to ground)

± 1500 V (DC

+ Peak AC)

1000 Vrms

Max. Input Voltage to Earth
(

either input to ground)

± 1500 Vpk

Max. Safe Input Voltage*
(per IEC 61010

-031)

1000 Vrms CAT III
Pollution Degree *

2

* See "IEC/EN 61010-031 Definitions" on p.38.

VERTICAL SENSITIVITY (ALL PROBES)

100 mV/Div to 500 V/Div.

Operator’s Manual

9

HVD310x / HVD310xA Bandwidth

HVD3102 / HVD3102A TYPICAL BANDWIDTH

HVD3106 / HVD3106A TYPICAL BANDWIDTH

HVD3000 / HVD3000A High-Voltage Differential Probes

10

HVD3106-6M / HVD3106A-6M TYPICAL BANDWIDTH

Operator’s Manual

11

HVD310x / HVD310xA Common Mode Rejection Ratio

HVD3102 / HVD3102A TYPICAL CMRR PERFORMANCE

HVD3106

/ HVD3102A TYPICAL CMRR PERFORMANCE

HVD3000 / HVD3000A High-Voltage Differential Probes

12

HVD310x / HVD310xA Voltage Derating and Burn Limit

The Maximum Input Voltage curve (solid line) shows the maximum voltage that can be
applied to the probe inputs without risking damage to the probe.

The lower Burn Limit curve (dashed line) shows the maximum voltage that can be applied
to the probe inputs while the operator is handling the inputs. Handling the inputs while
connected to active signals above this burn limit could result in injury to the operator.

WARNING. To avoid risk of electric shock or fire, comply with the burn limit when
measuring high-frequency signals with hand-held accessories. Do not exceed the
voltage or category rating of the probe or accessories (whichever is less). Keep your
fingers behind the finger guard of the probe. Keep the probe body and output cable
away from the circuits being measured. Use only the specified accessories.

HVD310x / HVD310xA Differential Input Impedance

Operator’s Manual

13

HVD3206 and HVD3206A Probes

Probe Kit

The probes are delivered with the following:

Item Description Safety Rating*

Part Number‡

QTY

2kV Plunger
Alligator
Clips

The clip is designed to securely grasp
thick wires, cables, ground leads, rails,
and screw heads. The overall length is
130 mm (5.1 inches); the jaw opens to
20 mm (0.79 inch) maximum. 4 mm
Banana (female) connector. 1 ea.
red/black.

2000 V (DC+Peak AC) CAT I**
1000 Vrms CAT III
1500 Vdc CAT III

PK-HVA-07 2

Case

Soft storage case SAC-01A 1

Foam

Custom foam insert for storage case 925955-00 1

Operator's
Manual

NA 1

* See "IEC/EN 61010-031 Definitions" on p.38.
** CAT I per IEC/EN 61010-031/A1:2008. No Rated Measurement Category per IEC/EN 61010-031:2015.
‡ See "Replacement Parts" on page 32 for information about ordering replacement accessories.

HVD3000 / HVD3000A High-Voltage Differential Probes

14

HVD3206 / HVD3206A Specifications

For the current specifications, see the product datasheet at teledynelecroy.com. Below are
some key product specifications.

Specifications are subject to change without notice.

GUARANTEED SPECIFICATIONS

HVD3206-6M/
HVD3206A-6M

Bandwidth

(probe only)

80 MHz

Risetime 10-90%

4.4 ns

CMRR Test Limits, 23 C

80 db @ 50 Hz
60 db @ 1 MHz

ELECTRICAL CHARACTERISTICS (ALL PROBES)

Max. Rated Diff. Voltage
(between each input)

2000

V (DC + Peak AC)

Max. Measurable Diff. Voltage
(before saturation)

2000 V (DC

+ Peak AC)

Max. Common Mode Voltage
(

either input to ground)

± 2000 V (DC + Peak AC)
1000 Vrms

Max. Input Voltage to Earth
(

either input to ground)

± 2000 Vpk (nominal, either input to ground)
± 2000 V

pk 2000 V (DC + peak AC) CAT I **

Max. Safe Input Voltage*
(per IEC 61010

-031)

1000 Vrms CAT III
1500 Vdc CAT III

Pollution Degree*

2

* See "IEC/EN 61010-031 Definitions" on p.38
** CAT I per IEC/EN 61010-031/A1:2008. No Rated Measurement Category per IEC/EN 61010-031:2015.

VERTICAL SENSITIVITY (ALL PROBES)

100 mV/Div to 500 V/Div.

Operator’s Manual

15

HVD3206 / HVD3206A Bandwidth

HVD3206 / HVD3206A TYPICAL BANDWIDTH

HVD3206-6M / HVD3206A-6M TYPICAL BANDWIDTH

HVD3000 / HVD3000A High-Voltage Differential Probes

16

HVD3206 / HVD3206A Common Mode Rejection Ratio

TYPICAL CMRR PERFORMANCE

Operator’s Manual

17

HVD3206 / HVD3206A Voltage Derating and Burn Limit

The Maximum Input Voltage curve (solid line) shows the maximum voltage that can be
applied to the probe inputs without risking damage to the probe.

The lower Burn Limit curve (dashed line) shows the maximum voltage that can be applied
to the probe inputs while the operator is handling the inputs. Handling the inputs while
connected to active signals above this burn limit could result in injury to the operator.

WARNING. To avoid risk of electric shock or fire, comply with the burn limit when
measuring high-frequency signals with hand-held accessories. Do not exceed the
voltage or category rating of the probe or accessories (whichever is less). Keep your
fingers behind the finger guard of the probe. Keep the probe body and output cable
away from the circuits being measured. Use only the specified accessories.

HVD3206 / HVD3206A Differential Input Impedance

HVD3000 / HVD3000A High-Voltage Differential Probes

18

HVD3605 and HVD3605A Probes

Probe Kit

The probes are delivered with the following:

Item Description Safety Rating*

Part Number‡

QTY

6kV Alligator
Clips

Designed to reliably grip large
components, such as bus bars and
large bolts, the overall length is 116
mm (4.57 inches) and the jaw opens
to 22 mm (0.87 inch). 1 ea. red/black.

6000 V CAT I**
1000 Vrms CAT III
1500 Vdc CAT III

PK-HVA-06 2

Case

Soft storage case SAC-01A 1

Foam

Custom foam insert for storage case. 925955-00 1

Operator's
Manual

NA 1

* See "IEC/EN 61010-031 Definitions" on p.38.
** CAT I per IEC/EN 61010-031/A1:2008. No Rated Measurement Category per IEC/EN 61010-031:2015.
‡ See "Replacement Parts" on page 32 for information about ordering replacement accessories.

Operator’s Manual

19

HVD3605 / HVD3605A Specifications

For the current specifications, see the product datasheet at teledynelecroy.com. Below are
some key product specifications.

Specifications are subject to change without notice.

GUARANTEED SPECIFICATIONS

Bandwidth

(probe only)

Risetime 10-90%

CMRR Test Limits, 23 C

dB @ 1 MHz (2000x)

ELECTRICAL CHARACTERISTICS (ALL PROBES)

Max. Rated Diff. Voltage
(between each input)

7000 V (DC + Peak AC)

Max. Measurable Diff. Voltage
(before saturation)

7600 V (DC + Peak AC)

Max. Common Mode Voltage
(

either input to ground)

± 7600 V (DC + Peak AC)
6000 Vrms

Max. Input Voltage to Earth
(

either input to ground)

± 7600 Vpk (nominal, either input to ground)
± 8485 V (DC + peak AC) CAT I **

Max. Safe Input Voltage*
(per IEC 61010

-031)

6000 Vrms CAT III
1000 Vrms CAT III
1500 Vdc CAT III

Pollution Degree*

2

* See "IEC/EN 61010-031 Definitions" on p.38
** CAT I per IEC/EN 61010-031/A1:2008. No Rated Measurement Category per IEC/EN 61010-031:2015.

VERTICAL SENSITIVITY (ALL PROBES)

300 mV/Div to 2000 V/Div.

HVD3000 / HVD3000A High-Voltage Differential Probes

20

HVD3605 / HVD3605A Bandwidth

TYPICAL BANDWIDTH

HVD3605 / HVD3605A Common Mode Rejection Ratio

TYPICAL CMRR PERFORMANCE

Operator’s Manual

21

HVD3605 / HVD3605A Voltage Derating and Burn Limit

The Maximum Input Voltage curve (solid line) shows the maximum voltage that can be
applied to the probe inputs without risking damage to the probe.

The lower Burn Limit curve (dashed line) shows the maximum voltage that can be applied
to the probe inputs while the operator is handling the inputs. Handling the inputs while
connected to active signals above this burn limit could result in injury to the operator.

WARNING. To avoid risk of electric shock or fire, comply with the burn limit when
measuring high-frequency signals with hand-held accessories. Do not exceed the
voltage or category rating of the probe or accessories (whichever is less). Keep your
fingers behind the finger guard of the probe. Keep the probe body and output cable
away from the circuits being measured. Use only the specified accessories.

HVD3605 / HVD3605A Differential Input Impedance

HVD3000 / HVD3000A High-Voltage Differential Probes

22

Functional Test Procedure

This procedure should be performed to confirm the basic operation of an HVD3000 or
HVD3000A probe or to aid in determining the source of a problem rather than to verify the
accuracy of the probe. You can perform the Functional Test without removing the probe
covers.

Other than a Teledyne LeCroy oscilloscope, no special test equipment is required for the
functional test.

1. Connect the probe to any oscilloscope vertical channel and open the Cn dialog.

2. Touch

AUTO ZERO on the probe dialog (behind the Cn dialog).

3. If necessary, adjust the

OFFSET to 0.000 V.

4. Using accessory clips, attach the red clip to the + CAL out and the black clip to the
ground post of the CAL out signal. For oscilloscopes with the CAL signal on a BNC
connector, a BNC-to-Banana adapter (e.g., Pomona model 1296) may be used.

5. Press

AUTOSETUP.

6. Set the sensitivity of the probe to 1 V/Div.

7. Set the CAL output to 1 Vp-p square wave.

8. Verify that the displayed square wave is 1 Vp-p centered at +0.5 V.

9. Reverse the accessory leads on CAL out and verify that the displayed square wave
is still 1 V, but is now centered at –0.5 V.

10. Change the

COUPLING on the channel setup dialog to Grounded to verify that the

signal disappears and that the trace is still centered on the screen.

11. Verify that the probe attenuation shows the following:

•

x100 for HVD3102 and HVD3102A

•

x50 for HVD3106, HVD3106A, HVD3206, and HVD3206A

•

x200 for HVD3605 and HVD3605A

12. Set the VOLTS/DIV to 100 V.

13. Verify that the probe attenuation now shows:

•

x1K for HVD3102 and HVD3102A

•

x500 for HVD3106, HVD3106A, HVD3206, and HVD3206A

•

x2K for HVD3605 and HVD3605A

Operator’s Manual

23

Performance Verification Procedure

This procedure can be used to verify the warranted characteristics of an HVD3000 or
HVD3000A probe. If the product does not meet specifications, it should be returned to a
Teledyne LeCroy service center. As there are no user accessible adjustments, there is no
adjustment procedure.

Required Equipment

The following table lists the test equipment and accessories (or their equivalents) that are
required for performance verification of the probe. This procedure is designed to minimize
the number of calibrated test instruments required. Because the input and output
connector types may vary on different brands and models of test instruments, additional
adapters or cables may be required. Only the parameters listed in boldface in the "Minimum
requirements" column must be calibrated to the accuracy indicated.

Description

Requirements

Example Equipment

Digital Multimeter

DC: 0.1% accuracy
AC: 0.2% accuracy to measure

7 mVrms to 37 Vrms at 70 Hz

Agilent 34401A

Fluke 8842A-09
Keithley 2001

Function Generator

Output sine wave:
20 Vpp HVD310x and HVD3602
37 Vrms HVD3605*

* May require an amplifier to obtain
required voltage, such as Tegam

2340.

Agilent 33120A
Stanford Research DS34
Leader LAG-120B

BNC Coaxial Cable

Male-to-Male 50 Ω Cable

Pomona 5697-36

Calibration Fixture

ProBus Extender Cable

Teledyne LeCroy PROBUS-CF01

Banana Plug Adapter Female BNC-to-Dual

Banana Plug

Pomona 1269 Mueller BU-00260

Insulated Banana Plug
Insulated Banana Couplers (2)

Insulated BNC-to-Shrouded
Banana Plug

Mueller BU-5671-B-12-0
Mueller BU-32601-2 (R)

Mueller BU-32601-6 (B)

HVD3000 / HVD3000A High-Voltage Differential Probes

24

Preliminary Procedure

1. Connect the probe under test to the female end of the ProBus Extension Cable.
Connect the male end of the ProBus Extension Cable to channel 1 (C1) of the
oscilloscope.

2. Turn on the oscilloscope and allow at least 30 minutes warm-up time before
performing the Certification Procedure.

3. Turn on the other test equipment and allow these to warm up for the time
recommended by the manufacturer.

4. While the instruments are reaching operating temperature, make a photocopy of
the Performance Verification Test Record (following this topic), and fill in the
necessary data.

Certification Procedure

1. Set the function generator to sine wave, 70 Hz, and an output voltage of
approximately:

• 7 Vrms (into a high impedance output) for HVD310x, HVD310xA, HVD3206,
and HVD3206A

• 37 Vrms for HVD3605 and HVD3605A

2. Set the DMM to measure AC Volts.

3. Connect the function generator output to the DMM, using a BNC cable and a female
BNC to dual banana plug adapter.

4. Adjust the function generator output voltage until the DMM reads:

•

7 V ±0.01 V for

HVD310x, HVD310xA, HVD3206, and HVD3206A

•

37 V ±0.01 V for HVD3605 and HVD3605A

5. Record the DMM reading to 1 mV resolution in the Test Record.

6. Disconnect the BNC cable from the function generator and from the BNC-to-banana
plug adapter on the DMM. (Leave the banana plug adapter connected to the DMM).

7. Connect the BNC connector from the probe extender cable to the BNC-to-banana
plug adapter on the DMM.

8. Connect the insulated banana plug adapter to the function generator.

Operator’s Manual

25

9. Using the insulated banana couplers, connect the positive lead (red) of the probe

under test to the positive output of the BNC-to-banana plug adapter and the
negative lead (black) to the negative or return output.

10. Set the oscilloscope scale factor to:

•

20 V/Div for

HVD310x, HVD310xA, HVD3206, and HVD3206A

•

50 V/Div for HVD3605 and HVD3605A

11. Record the DMM reading to 0.01 mV resolution in the Test Record.

12. Multiply the measured output voltage recorded in step 11 by the actual probe

attenuation factor, then divide this number by the function generator output voltage
(probe input voltage) recorded in step 5. Subtract 1 from this number and multiply
the result by 100 to get the error in percent:

NOTE: The actual probe attenuation can be found by using the XStreamBrowser.
Follow the procedure below.

13. Record the answer to two significant places (± x.xx%) on line 13 in the Test Record.

14. Verify that the error ≤ 1.00%.

15. Decrease the oscilloscope scale factor to 5 V/Div.

16. Record the DMM reading to 0.01 mV resolution in the Test Record.

17. Multiply the measured output voltage recorded in step 16 by the actual probe

attenuation factor, then divide this number by the function generator output voltage
(probe input voltage) recorded in step 5. Subtract 1 from this number and multiply
the result by 100 to get the error in percent.

NOTE: Recheck the actual probe attenuation in the XStreamBrowser, as it will now
be a different value than in step 12. Click the Refresh button in XStreamBrowser if
the previous session is still open.

18. Record the answer to two significant places (±x.xx%) on line 18 in the Test Record.

19. Verify that the error is ≤ 1.00%.

20. This completes the Performance Verification Procedure. Complete and file the Test

Record as required to support your internal calibration procedure. If the criteria in
steps 14 or 19 are not met, contact your local Teledyne LeCroy service center.

HVD3000 / HVD3000A High-Voltage Differential Probes

26

Checking Probe Attenuation in XStreamBrowser

Probe attenuation and other values can be found by using the XStreamBrowser application
that is installed with the oscilloscope firmware.

1. Choose

File > Minimize to show the oscilloscope desktop, then double-click the

XStreamBrowser icon.

2. From the browser menu bar, choose

File > Connect to Local Instrument.

3. Navigate to

LeCroy.XStreamDSO > Acquisition > C1 > InputB > HVDxxxxx (where

xxxxx is your probe model number). The value is shown next to PrAttenuation.

4. Close XStreamBrowser and touch the oscilloscope icon (bottom right of desktop) to
return to the oscilloscope software.

NOTE: These steps are tailored to the Performance Verification procedure. You can find any
value at any time by changing the path to reflect the probe's actual input channel and row
(Cn > Input A|B).

Operator’s Manual

27

HVD3000 / HVD3000A Test Record

Serial Number:____________________________________________________

Asset / Tracking Number: _________________________________________

Date:______________________________________________________________

Technician:________________________________________________________

Equipment

Model

Serial Number

Calibration Due Date

Oscilloscope

Digital Multimeter

Function Generator*

* In this Performance Verification Procedure, the function generator is used for making relative measurements. The
output of the generator is measured with a DMM or oscilloscope. Thus, the generator is not required to be calibrated.

Step

Description

Intermediate Data

Test Result

5 Function Generator Output Voltage V

11 Probe Output Voltage V

13 Gain Error (test limit ± 1 %) %

16 Probe Output Voltage V

18 Gain Error (test limit ± 1 %) %

Permission is granted to photocopy this page to record the results of the Performance Verification procedure.
File the completed record as required by applicable internal quality procedures.

• Line numbers correspond to steps in the procedure that require the recording of data.

• Record the actual specification limit check under "Test Result". The test limits are included in all of

these steps.

• Record other measurements and intermediate calculations that support the limit check under

"Intermediate Results".

HVD3000 / HVD3000A High-Voltage Differential Probes

28

Operation

Connecting to the Test Instrument

HVD3000 and HVD3000A probes have been designed for use with Teledyne LeCroy
oscilloscopes equipped with the ProBus interface. When you attach the probe to the
oscilloscope’s input connector, the instrument will:

• Recognize the probe

• Set the oscilloscope input termination to 1 MΩ

• Activate the probe control functions in the oscilloscope user interface

NOTE: For accurate measurements, connect the probe to the oscilloscope and allow it to
warm up for at least 20 minutes. When using HVD3000 probes, perform Auto Zero prior to
connecting probe leads to the DUT. HVD3000A probes may be connected to the DUT
during Auto Zero.

Connecting to the Test Circuit

Two inputs are available at the probe tip to connect the probe to a circuit under test. For
accurate measurements, both the + and – inputs must be connected to the test circuit.
Positive voltages applied to the + input (red) relative to the – input (black) will deflect the
oscilloscope trace toward the top of the screen.

To maintain the probe's high performance capability, exercise care when connecting the
probe. Increasing the parasitic capacitance or inductance in the input paths may introduce
a “ring” or slow the rise time of fast signals. Input leads that form a large loop area will pick
up any radiated electromagnetic field that passes through the loop and may induce noise
into the probe inputs. Because this signal will appear as a differential mode signal, the
probe’s common mode rejection will not remove it. This effect can be reduced by twisting
the input leads together to minimize the loop area.

WARNING. To avoid electric shock or fire, maintain the input leads in good
condition. The leads have a jacket wear indicator that shows through when the
jacket is excessively worn. If the white "WEAR" indicator on the input leads is
visible, cease use and contact Teledyne LeCroy service for repair or replacement.

High common mode rejection requires precise matching of the relative gain or attenuation
in the + and – input signal paths. Mismatches in additional parasitic capacitance,
inductance, delay, and a source impedance difference between the + and – signals will
lower the CMRR. Therefore, it is desirable to use the same length and type of wire and
connectors for both input connections. When possible, try to connect the inputs to points in

Operator’s Manual

29

the circuit with approximately the same source impedance.

The probes may be stacked on one top of another during usage to conserve space. Since
the probe body generates heat, and the stacking reduces cooling, it is recommended that
ambient temperatures not exceed 30 degrees C while stacked probes are in operation. The
exceptional CMRR performance should prevent interference between probes when they are
stacked, but take care to separate the probe leads during operation.

WARNING. To avoid electric shock or fire, keep the probe body and output cable
away

from the circuits being measured, as they cannot provide adequate protection

if they come in contact with electrical sources.

Operating with an Oscilloscope

When the probe is connected to a Teledyne LeCroy oscilloscope, the displayed scale factor
and measurement values will be adjusted to account for the effective gain of the probe.
The probe’s internal attenuation is shown on the Probe dialog, which is added to the
oscilloscope's input channel dialogs when a probe is detected.

Channel setup dialog with Probe dialog behind it.

Probe dialog.

Probe Volts/Div and Attenuation

The front panel Volts/Div knob controls the oscilloscope’s scale factor and the probe’s
internal attenuation to give full available dynamic range. Some transition of the scale factor
will result in a change of attenuation.

HVD3000 / HVD3000A High-Voltage Differential Probes

30

Offset

Offset allows you to remove a DC bias voltage from the differential input signal while
maintaining DC coupling. This ensures that the probe will never be overdriven while a signal
is displayed on screen and prevents inaccurate measurements.

The total usable offset of the oscilloscope and probe system is a function of the
oscilloscope V/div setting and offset at that V/div setting, and the probe attenuation and
offset at that attenuation setting. Total maximum offset may be calculated as:

Oscilloscope Front End V/Div = (Probe and Oscilloscope) V/Div ÷ Probe_Attenuation

Once the oscilloscope front end V/div value is known, it is possible to know the maximum
oscilloscope offset available at this V/div setting either by referencing the oscilloscope
specifications or setting the maximum offset value on the oscilloscope for that V/div
setting. Maximum offset for the probe and oscilloscope combination can then be
calculated as:

Max Positive Offset Available

Max Positive Offset (Probe and Oscilloscope together) =

Oscilloscope Positive Offset (at Oscilloscope Front End V/div) * Probe Attenuation– 10V

Max Negative Offset Available

Max Negative Offset (Probe and Oscilloscope together) =

Oscilloscope Negative Offset (at Oscilloscope Front End V/div) * Probe Attenuation + 10V

In both cases, the maximum offset available cannot exceed the following:

X50 X100 X200 X500 X1000 X2000

3102 / 3102A

NA

±150V

NA

NA

±1500V

NA

3106 / 3106A

±150V

NA

NA

±1500V

NA

NA

3206 / 3206A

±150V

NA

NA

±1500V

NA

NA

3605 / 3605A

NA

NA

±600V

NA

NA

±6000V

NOTE: The offset values reported on oscilloscope channel descriptor boxes may deviate
slightly from expected values per the formulas above. The reported probe attenuation is a
"nominal" value and can deviate slightly from the actual value measured during calibration
and stored with the probe. The actual offset value reported uses the actual "as measured"
probe attenuation value. This provides for higher DC and low frequency gain accuracy than
would otherwise be possible.

Operator’s Manual

31

AC Coupling

In general, using offset to adjust a differential DC voltage on the screen is the preferred
method to measure transient signals in the presence of a larger DC voltage. The offset has
limits that will cause a signal that is beyond the linear operating range of the probe to go
off the screen, preventing measurement errors.

There are times, however, when it is convenient to use AC coupling to remove the DC

component of the measured signal from the measurement. Selecting AC10MΩ uses the

scope AC coupling at the probe output to remove any steady state value from the displayed
voltage. The maximum linear input voltage is as follows:

X50
<7 V/div

X100
<7 V/div

X200
<28 V/div

X500
>7 V/div

X1000
>7 V/div

X2000
>28 V/div

3102 / 3102A

NA

200 Vpk

NA

NA

1750 Vpk

NA

3106 / 3106A

200 Vpk

NA

NA

2000 Vpk

NA

NA

3206 / 3206A

200 Vpk

NA

NA

2000 Vpk

NA

NA

3605 / 3605A

NA

NA

760 Vpk

NA

NA

7600 Vpk

NOTE: Because AC coupling is on the probe output, DC voltages beyond the probe’s linear
range will cause the amplifier to saturate and inaccurately render the displayed waveform.
Do not exceed the maximum linear input value when using AC coupling.

Bandwidth Limiting

To comply with various test standards used for quantifying output noise of power supplies,
the probe is capable of switching the bandwidth limit from Off (maximum bandwidth) to 20
MHz in the channel Vertical Adjust dialog.

Voltage Range

On oscilloscopes running XStreamDSO v.8.5.x.x and higher, there are two options as to how
the probe will set attenuation relative to the oscilloscope’s V/div setting:

Auto will automatically raise the attenuation when the V/div setting is >7.9V/div or lower
the attenuation when the V/div is <7.9V/div. As a result the probe can automatically adjust
attenuation to properly view the input waveform.

Lock to High locks the attenuation setting to the highest attenuation, regardless of the
V/div setting. Maintaining a high attenuation will allow small signals on a larger voltage
waveform to be accurately measured.

HVD3000 / HVD3000A High-Voltage Differential Probes

32

Overload Indicator (A models only)

On HVD3000A probes, an indication will appear in the oscilloscope message bar when the
differential or common mode voltages are beyond the operating ranges of the probe. Note
that the warning message below may trigger before any saturation occurs. It is designed to
guarantee that the system will not fail to indicate an overload.

Overload Indicator Thresholds

3102A

X1000 Attenuation

X100 Attenuation

Differential Mode: ± 1.78 kV
Common Mode: ± 1.78 kV

Differential Mode: ± 158 V
Common Mode: ± 1.8k V

3206A

X500 Attenuation

X50 Attenuation

Differential Mode: ± 2.1 kV
Common Mode: ± 2.1 kV

Differential Mode: ± 180 V
Common Mode: ± 2.1 kV

3605A

X2000 Attenuation

X200 Attenuation

Differential Mode: ± 7.7 kV
Common Mode: ± 7.7 kV

Differential Mode: ± 760 V
Common Mode: ± 7.7 kV

Auto Zero

Auto Zero corrects for DC offset drifts that naturally occur from thermal effects in the
differential amplifier. For example, the DC offset drift of the HVD310x and HVD310xA
probes is 70 μV/°C (worst case) referred to the output. If the probe is set to 50x attenuation
and the ambient temperature changes by 10 °C, the DC offset drift could be as high as (70
μV/°C)(50)(10 °C) = 35 mV referred to the probe tip. If measuring a 3 Vp-p signal, the DC
offset drift could be a little more than 1%. If the signal was 1400 Vp-p in 500x attenuation
mode, the DC offset drift at same ambient temperature could be as high as (70
μV/°C)(500)(10°C) = 350 mV due to the probe tip (although any offset accuracy error from
the oscilloscope itself would likely dominate the measurement).

Auto Zero is invoked manually from the Probe dialog that appears behind the Channel
setup dialog when the probe is connected to the oscilloscope.

NOTE: When using HVD3000 probes, disconnect the probe from the test circuit before
performing Auto Zero. HVD3000A probes may remain connected during Auto Zero.

Always perform Auto Zero after the probe has been warmed-up (20 min. recommended).
Depending on the measurement accuracy desired and/or the change in the ambient
temperature where the probe is located, it may be necessary to perform Auto Zero more
often. If the probe is disconnected from the oscilloscope then re-connected, repeat Auto
Zero after a suitable warm-up time.

Auto Zero is disabled when AC coupling is selected.

Operator’s Manual

33

Maintenance

Cleaning

Clean only the exterior surfaces of the device using a soft cloth or swab dampened with
water or 75% isopropyl alcohol solution. Do not use harsh chemicals or abrasive cleansers.
Dry the probe and accessories thoroughly before making any voltage measurements.

CAUTION. The probes are not waterproof. Under no circumstances submerge the
probe in liquid or allow moisture to penetrate it.

Calibration Interval

This probe has no adjustments. The recommended calibration interval is one year. A
Performance Verification Procedure is included in this manual.

Service Strategy

HVD3000 and HVD3000A probes utilize fine-pitch surface mount devices. It is, therefore,
impractical to attempt repair in the field. Defective probes must be returned to a Teledyne
LeCroy service facility for diagnosis and exchange.

CAUTION. Do not remove the covers. Refer all servicing to qualified personnel. A
defective probe under warranty will be replaced with a factory refurbished probe.

A probe that is not under warranty can be exchanged for a factory refurbished probe for a
modest fee. Replacement probes are factory repaired, inspected, and calibrated to the
same standards as a new product. You must return the defective probe in order to receive
credit for the probe core.

Replacement Parts

Replacement probe accessories can be ordered through your local sales office:

Probe

Replacement Parts

Part Number

HVD310x / HVD310xA

Probe Accessory Kit *

PK-HV-001

HVD3206 / HVD3206A

2kV Alligator Clips

PK-HVA-07

HVD3605 / HVD3605A

6kV Alligator Clips

PK-HVA-06

* Individual probe accessory tips can be purchased through your regional service center. Refer to the
accessory part numbers listed earlier in this manual.

HVD3000 / HVD3000A High-Voltage Differential Probes

34

Returning a Product for Service

Contact your regional Teledyne LeCroy service center for calibration or other service. If the
product cannot be serviced on location, the service center will give you a

Return Material
Authorization (RMA) code and instruct you where to ship the product. All products returned
to the factory must have an RMA.

Return shipments must be prepaid. Teledyne LeCroy cannot accept COD or Collect
shipments. We recommend air-freighting. Insure the item you’re returning for at least the
replacement cost.

1. Remove all accessories from the device.

2. Pack the product in its case, surrounded by the original packing material (or
equivalent). Do not include the manual.

3. Label the case with a tag containing:

• The RMA

• Name and address of the owner

• Product model and serial number

• Description of failure or requisite service

4. Pack the product case in a cardboard shipping box with adequate padding to avoid
damage in transit.

5. Mark the outside of the box with the shipping address given to you by Teledyne
LeCroy; be sure to add the following:

• ATTN: <RMA code assigned by Teledyne LeCroy>

• FRAGILE

6. If returning a product to a different country:

• Mark the shipment as a "Return of US manufactured goods for warranty
repair/recalibration."

• If there is a cost for the service, list the cost in the Value column and the
original purchase price "For insurance purposes only."

• Be very specific about the reason for shipment. Duties may have to be paid
on the value of the service.

Extended warranty, calibration, and upgrade plans are available for purchase. Contact your
Teledyne LeCroy sales representative.

Operator’s Manual

35

Technical Support

Live Support

Registered users can contact their local Teledyne LeCroy service center at the number
listed on our website.

You can also submit Technical Support requests via the website at:
teledynelecroy.com/support/techhelp

Resources

Teledyne LeCroy publishes a free Technical Library on its website. Manuals, tutorials,
application notes, white papers, and videos are available to help you get the most out of
your Teledyne LeCroy products.

The Datasheet published on the product page contains the detailed product specifications.

Service Centers

For a complete list of offices by country, including our sales & distribution partners, visit:
teledynelecroy.com/support/contact

Teledyne LeCroy
700 Chestnut Ridge Road
Chestnut Ridge, NY, 10977, USA
teledynelecroy.com

Sales and Service:
Ph: 800-553-2769 / 845-425-2000

FAX: 845-578-5985
contact.corp@teledynelecroy.com

Support:
Ph: 800-553-2769

customersupport@teledynelecroy.com

HVD3000 / HVD3000A High-Voltage Differential Probes

36

Reference

Common Mode Rejection Ratio

The ideal differential probe/amplifier would sense and amplify only the differential mode
voltage component and reject the entire common mode voltage component. Real
differential amplifiers are not perfect, and a small portion of the common mode voltage
component appears at the output.

Common Mode Rejection Ratio (CMRR) is the measure of how much the amplifier rejects
the common mode voltage component. CMRR is equal to the differential mode gain (or
normal gain) divided by the common mode gain. Common mode gain is equal to the output
voltage divided by the input voltage when both inputs are driven by only the common mode
signal. CMRR can be expressed as a ratio (e.g., 10,000:1) or implicitly in dB (e.g., 80 dB).
Higher numbers indicate greater rejection (better performance).

The first order term determining the CMRR is the relative gain matching between the + and
– input paths. Obtain high CMRR values by precisely matching the input attenuators in a
differential amplifier. The matching includes the DC attenuation and the capacitance which
determines the AC attenuation. As the frequency of the common mode component
increases, the effects of stray parasitic capacitance and inductance in determining the AC
component become more pronounced. The CMRR becomes smaller as the frequency
increases. Therefore, the CMRR is usually specified in a graph of CMRR versus common
mode frequency.

The common mode frequency in these graphs is assumed to be sinusoidal. In real life
applications, the common mode signal is seldom a pure sine wave. Signals with pulse wave
shapes contain frequency components much higher than the repetition rate may suggest.
This makes it very difficult to predict actual performance in the application for CMRR­versus- frequency graphs. The practical application of these graphs is to compare the
relative common mode rejection performance between different probes and amplifiers.

Operator’s Manual

37

Differential Mode and Common Mode

Differential probes sense the voltage difference that appears between the + and – inputs.
This is referred to as the Differential or Normal Mode voltage. The voltage component that
is referenced to earth and is identical on both inputs is rejected by the amplifier. This is
referred to as the Common Mode voltage and can be expressed as:

Differential Mode Range and Common Mode Range

Differential Mode range is the maximum signal that can be applied between the + and ­inputs without overloading the amplifier, which otherwise would result in clipping or
distorting of the waveform measured by the oscilloscope.

The Common Mode Range is the maximum voltage with respect to earth ground that can
be applied to either input. Exceeding the common mode range can result in unpredictable
measurements. Because the Common Mode signal is normally rejected, and not displayed
on the oscilloscope, be careful to avoid accidentally exceeding the common mode range.

HVD3000 / HVD3000A High-Voltage Differential Probes

38

IEC/EN 61010-031 Definitions

IEC/EN 61010-031/A1:2008

Measurement Category III (CAT III) applies to test and measuring circuits connected to the
distribution part of the building’s low-voltage mains installation.

Measurement Category II (CAT II) applies to test and measuring circuits connected directly
to utilization points (socket outlets and similar points) of the low-voltage mains installation.

Measurement Category I (CAT I) applies to test and measurement circuits that are not
intended to be directly connected to the mains supply.

Pollution Degree 2 refers to an operating environment where normally only dry non­conductive pollution occurs. Conductivity caused by temporary condensation should be
expected.

IEC/EN 61010-031:2015

Measurement Category III (CAT III) applies to test and measuring circuits connected to the
distribution part of the building’s low-voltage mains installation.

Measurement Category II (CAT II) applies to test and measuring circuits connected directly
to utilization points (socket outlets and similar points) of the low-voltage mains installation.

No Rated Measurement Category applies to other circuits that are not directly connected to
the mains supply.

Pollution Degree 2 refers to an operating environment where normally only dry non­conductive pollution occurs. Conductivity caused by temporary condensation should be
expected.

NOTE: The 2015 version of the standard eliminates the Measurement Category I (CAT I)
rating for test and measuring circuits that are not intended to be directly connected to the
mains supply. However, this change in rating designation does not reduce the
measurement capability or the level of protection offered by the new probe design when
compared to the probes that were originally certified per the 2008 version of the standard.

Operator’s Manual

39

Certifications

Teledyne LeCroy certifies compliance to the following standards as of the time of
publication. As standards evolve, these certifications may no longer be current. Please see
the EC Declaration of Conformity certificate shipped with your product.

EMC Compliance

EC Declaration of Conformity - EMC

The probe meets the intent of EC Directive 2014/30/EU for Electromagnetic Compatibility.
Compliance was demonstrated to the following specifications as listed in the Official
Journal of the European Communities:

EN 61326-1:2013, EMC requirements for electrical equipment for measurement, control,
and laboratory use.

1, 2, 3

1. This product is intended for use in nonresidential areas only. Use in residential areas may cause EM interference.

2. Emissions exceeding the levels required by this standard may occur when product is connected to a test object.

3. To ensure compliance with the applicable EMC standards, use high quality shielded interface cables.

EUROPEAN CONTACT:*

Teledyne LeCroy Europe GmbH
Im Breitspiel 11c
D-69126 Heidelberg Germany
Tel: + 49 6221 82700

Australia & New Zealand Declaration of Conformity—EMC

The probe complies with the EMC provision of the Radio Communications Act per the
following standards, in accordance with requirements imposed by Australian
Communication and Media Authority (ACMA):

AS/NZS CISPR 11:2011 Radiated and Conducted Emissions, Group 1, Class A.

AUSTRALIA / NEW ZEALAND CONTACTS:*

RS Components Pty Ltd.

Suite 326 The Parade West
Kent Town, South Australia 5067

RS Components Ltd.

Unit 30 & 31 Warehouse World
761 Great South Road
Penrose, Auckland, New Zealand

* Visit teledynelecroy.com/support/contact for the latest contact information.

HVD3000 / HVD3000A High-Voltage Differential Probes

40

Safety Compliance

EC Declaration of Conformity - Low Voltage

The probe meets the intent of EC Directive 2014/35/EU for Product Safety. Compliance
was demonstrated to the following specifications as listed in the Official Journal of the
European Communities:

IEC/EN 61010-031:2015 Safety requirements for electrical equipment for measurement,
control, and laboratory use – Part 031: Safety requirements for hand-held probe
assemblies for electrical measurement and test.

U.S. Nationally Recognized Agency Certification

The probe has been certified by Underwriters Laboratories (UL) to conform to the following
safety standard and bears UL Listing Mark:

UL 61010-031-2015 (Second Edition) - Safety Requirements for Electrical Equipment for
Measurement, Control, and Laboratory Use - Part 031: Safety Requirements for Hand-Held
Probe Assemblies for Electrical Measurement and Test.

Canadian Certification

The probe has been certified by Underwriters Laboratories (UL) to conform to the following
safety standard and bears cUL Listing Mark:

CAN/CSA-C22.2 No. 61010-031-15 - Safety Requirements for Electrical Equipment for
Measurement, Control, and Laboratory Use - Part 031: Safety Requirements for Hand-Held
Probe Assemblies for Electrical Measurement and Test.

Environmental Compliance

End-of-Life Handling

The product is marked with this symbol to indicate that it complies with the
applicable European Union requirements to Directives 2012/19/EU and
2013/56/EU on Waste Electrical and Electronic Equipment (WEEE) and Batteries.

The product is subject to disposal and recycling regulations that vary by country
and region. Many countries prohibit the disposal of waste electronic equipment in standard
waste receptacles. For more information about proper disposal and recycling of your
Teledyne LeCroy product, please visit teledynelecroy.com/recycle.

Restriction of Hazardous Substances (RoHS)

The product and its accessories conform to the 2011/65/EU RoHS2 Directive.

930490-00 Rev A
November, 2018