TiePie Handyscope HS3 User manual
Handyscope HS3
User manual
TiePie engineering
ATTENTION!
Measuring directly on the line voltage can be very dangerous.
The outside of the BNC connectors at the Handyscope HS3 are
connected with the ground of the computer. Use a good isolation
transformer or a differential probe when measuring at the line volt-
age or at grounded power supplies! A short-circuit current will
flow if the ground of the Handyscope HS3 is connected to a positive
voltage. This short-circuit current can damage both the Handyscope
HS3 and the computer.
Copyright c
2016 TiePie engineering.
All rights reserved.
Revision 2.16, June 2016
Despite the care taken for the compilation of this
user manual, TiePie engineering can not be held
responsible for any damage resulting from errors
that may appear in this manual.
Contents
1 Safety 1
2 Declaration of conformity 3
3 Introduction 5
3.1 Sampling ........................ 6
3.2 Sample frequency .................... 7
3.2.1 Aliasing ..................... 7
3.3 Digitizing ........................ 9
3.4 Signal coupling ..................... 10
3.5 Probe compensation .................. 10
4 Driver installation 13
4.1 Introduction ....................... 13
4.2 Where to find the driver setup ............ 13
4.3 Executing the installation utility ........... 13
5 Hardware installation 19
5.1 Power the instrument ................. 19
5.1.1 External power ................. 19
5.2 Connect the instrument to the computer ....... 20
5.2.1 Found New Hardware Wizard ......... 21
5.3 Plug into a different USB port ............ 23
6 Front panel 25
6.1 CH1 and CH2 input connectors ............ 25
6.2 GENERATOR output connector ........... 25
6.3 Power indicator ..................... 25
7 Rear panel 27
7.1 Power .......................... 27
7.1.1 USB power cable ................ 28
7.1.2 Power adapter ................. 29
7.2 USB ........................... 29
7.3 Extension Connector .................. 29
8 Specifications 31
8.1 Acquisition system ................... 31
Contents I
8.2 BNC inputs CH1, CH2 ................. 31
8.3 Trigger system ..................... 32
8.4 Arbitrary Waveform Generator ............ 32
8.5 Interface ......................... 33
8.6 Power .......................... 33
8.7 Physical ......................... 33
8.8 I/O connectors ..................... 33
8.9 System requirements .................. 33
8.10 Environmental conditions ............... 33
8.11 Certifications and Compliances ............ 34
8.12 Probes .......................... 34
8.13 Package contents .................... 34
II
Safety 1
When working with electricity, no instrument can guaran-
tee complete safety. It is the responsibility of the person
who works with the instrument to operate it in a safe way.
Maximum security is achieved by selecting the proper in-
struments and following safe working procedures. Safe
working tips are given below:
•Always work according (local) regulations.
•Work on installations with voltages higher than 25 VAC or
60 VDC should only be performed by qualified personnel.
•Avoid working alone.
•Observe all indications on the Handyscope HS3 before con-
necting any wiring
•Check the probes/test leads for damages. Do not use them
if they are damaged
•Take care when measuring at voltages higher than 25 VAC or
60 VDC.
•Do not operate the equipment in an explosive atmosphere or
in the presence of flammable gases or fumes.
•Do not use the equipment if it does not operate properly.
Have the equipment inspected by qualified service personal.
If necessary, return the equipment to TiePie engineering for
service and repair to ensure that safety features are main-
tained.
•Measuring directly on the line voltage can be very danger-
ous. The outside of the BNC connectors at the Handy-
scope HS3 are connected with the ground of the computer.
Use a good isolation transformer or a differential probe when
measuring at the line voltage or at grounded power sup-
plies! A short-circuit current will flow if the ground of the
Handyscope HS3 is connected to a positive voltage. This
short-circuit current can damage both the Handyscope HS3
and the computer.
Safety 1
2Chapter 1
Declaration of conformity 2
TiePie engineering
Koperslagersstraat 37
8601 WL Sneek
The Netherlands
EC Declaration of conformity
We declare, on our own responsibility, that the product
Handyscope HS3-5MHz
Handyscope HS3-10MHz
Handyscope HS3-25MHz
Handyscope HS3-50MHz
Handyscope HS3-100MHz
for which this declaration is valid, is in compliance with
EN 55011:2009/A1:2010 IEC 61000-6-1/EN 61000-6-1:2007
EN 55022:2006/A1:2007 IEC 61000-6-3/EN 61000-6-3:2007
according the conditions of the EMC standard 2004/108/EC,
also with
Canada: ICES-001:2004 Australia/New Zealand: AS/NZS
and
IEC 61010-1:2001/EN USA: UL61010-1: 2004
and is categorized as CAT I 30 Vrms, 42 Vpk, 60 Vdc
Sneek, 1-11-2010
ir. A.P.W.M. Poelsma
Declaration of conformity 3
Environmental considerations
This section provides information about the environmental impact
of the Handyscope HS3.
Handyscope HS3 end-of-life handling
Production of the Handyscope HS3 required the extraction and use
of natural resources. The equipment may contain substances that
could be harmful to the environment or human health if improperly
handled at the Handyscope HS3’s end of life.
In order to avoid release of such substances into the environment
and to reduce the use of natural resources, recycle the Handyscope
HS3 in an appropriate system that will ensure that most of the
materials are reused or recycled appropriately.
The symbol shown below indicates that the Handyscope HS3
complies with the European Union’s requirements according to Di-
rective 2002/96/EC on waste electrical and electronic equipment
(WEEE).
Restriction of Hazardous Substances
The Handyscope HS3 has been classified as Monitoring and Con-
trol equipment, and is outside the scope of the 2002/95/EC RoHS
Directive.
4Chapter 2
Introduction 3
Before using the Handyscope HS3 first read chapter 1about
safety.
Many technicians investigate electrical signals. Though the
measurement may not be electrical, the physical variable is of-
ten converted to an electrical signal, with a special transducer.
Common transducers are accelerometers, pressure probes, current
clamps and temperature probes. The advantages of converting the
physical parameters to electrical signals are large, since many in-
struments for examining electrical signals are available.
The Handyscope HS3 is a portable two channel measuring in-
strument with Arbitrary Waveform Generator. The Handyscope
HS3 is available in several models with different maximum sam-
pling frequencies: 5 MS/s, 10 MS/s, 25 MS/s, 50 MS/s or 100
MS/s. The native resolution is 12 bits, but user selectable resolu-
tions of 8, 14 and 16 bits are available too, with adjusted maximum
sampling frequency:
resolution Maximum sampling frequency
8 bit 100 MS/s
12 bit 5, 10, 25 or 50 MS/s, depending on model
14 bit 3.125 MS/s
16 bit 195 kS/s
Table 3.1: Maximum sampling frequencies
With the accompanying software the Handyscope HS3 can be
used as an oscilloscope, a spectrum analyzer, a true RMS voltmeter
or a transient recorder. All instruments measure by sampling the
input signals, digitizing the values, process them, save them and
display them.
Introduction 5
3.1 Sampling
When sampling the input signal, samples are taken at fixed inter-
vals. At these intervals, the size of the input signal is converted to a
number. The accuracy of this number depends on the resolution of
the instrument. The higher the resolution, the smaller the voltage
steps in which the input range of the instrument is divided. The
acquired numbers can be used for various purposes, e.g. to create
a graph.
Figure 3.1: Sampling
The sine wave in figure 3.1 is sampled at the dot positions. By
connecting the adjacent samples, the original signal can be recon-
structed from the samples. You can see the result in figure 3.2.
Figure 3.2: ”connecting” the samples
6Chapter 3
3.2 Sample frequency
The rate at which the samples are taken is called the sampling
frequency, the number of samples per second. A higher sampling
frequency corresponds to a shorter interval between the samples.
As is visible in figure 3.3, with a higher sampling frequency, the
original signal can be reconstructed much better from the measured
samples.
Figure 3.3: The effect of the sampling frequency
The sampling frequency must be higher than 2 times the high-
est frequency in the input signal. This is called the Nyquist fre-
quency. Theoretically it is possible to reconstruct the input signal
with more than 2 samples per period. In practice, 10 to 20 sam-
ples per period are recommended to be able to examine the signal
thoroughly.
3.2.1 Aliasing
When sampling an analog signal with a certain sampling frequency,
signals appear in the output with frequencies equal to the sum and
difference of the signal frequency and multiples of the sampling
frequency. For example, when the sampling frequency is 1000 Hz
and the signal frequency is 1250 Hz, the following signal frequencies
will be present in the output data:
Introduction 7
Multiple of sampling frequency 1250 Hz signal -1250 Hz signal
...
-1000 -1000 + 1250 = 250 -1000 - 1250 = -2250
0 0 + 1250 = 1250 0 - 1250 = -1250
1000 1000 + 1250 = 2250 1000 - 1250 = -250
2000 2000 + 1250 = 3250 2000 - 1250 = 750
...
Table 3.2: Aliasing
As stated before, when sampling a signal, only frequencies lower
than half the sampling frequency can be reconstructed. In this
case the sampling frequency is 1000 Hz, so we can we only observe
signals with a frequency ranging from 0 to 500 Hz. This means
that from the resulting frequencies in the table, we can only see
the 250 Hz signal in the sampled data. This signal is called an
alias of the original signal.
If the sampling frequency is lower than twice the frequency of
the input signal, aliasing will occur. The following illustration
shows what happens.
Figure 3.4: Aliasing
In figure 3.4, the green input signal (top) is a triangular signal
with a frequency of 1.25 kHz. The signal is sampled with a fre-
quency of 1 kHz. The corresponding sampling interval is 1/1000Hz
8Chapter 3
= 1ms. The positions at which the signal is sampled are depicted
with the blue dots. The red dotted signal (bottom) is the result
of the reconstruction. The period time of this triangular signal
appears to be 4 ms, which corresponds to an apparent frequency
(alias) of 250 Hz (1.25 kHz - 1 kHz).
To avoid aliasing, always start measuring at the highest sam-
pling frequency and lower the sampling frequency if required.
3.3 Digitizing
When digitizing the samples, the voltage at each sample time is
converted to a number. This is done by comparing the voltage
with a number of levels. The resulting number is the number cor-
responding to the level that is closest to the voltage. The number
of levels is determined by the resolution, according to the following
relation: LevelCount = 2Resolution.
The higher the resolution, the more levels are available and
the more accurate the input signal can be reconstructed. In figure
3.5, the same signal is digitized, using two different amounts of
levels: 16 (4-bit) and 64 (6-bit).
Figure 3.5: The effect of the resolution
The Handyscope HS3 measures at e.g. 12 bit resolution (212=4096
levels). The smallest detectable voltage step depends on the input
Introduction 9
range. This voltage can be calculated as:
V oltageStep =F ullInputRange/LevelCount
For example, the 200 mV range ranges from -200 mV to +200
mV, therefore the full range is 400 mV. This results in a smallest
detectable voltage step of 0.400V/4096 = 97.65 µV.
3.4 Signal coupling
The Handyscope HS3 has two different settings for the signal cou-
pling: AC and DC. In the setting DC, the signal is directly coupled
to the input circuit. All signal components available in the input
signal will arrive at the input circuit and will be measured.
In the setting AC, a capacitor will be placed between the input
connector and the input circuit. This capacitor will block all DC
components of the input signal and let all AC components pass
through. This can be used to remove a large DC component of the
input signal, to be able to measure a small AC component at high
resolution.
When measuring DC signals, make sure to set the signal
coupling of the input to DC.
3.5 Probe compensation
The Handyscope HS3 is shipped with a probe for each input chan-
nel. These are 1x/10x selectable passive probes. This means that
the input signal is passed through directly or 10 times attenuated.
When using an oscilloscope probe in 1:1 the setting, the
bandwidth of the probe is only 6 MHz. The full bandwidth
of the probe is only obtained in the 1:10 setting
The x10 attenuation is achieved by means of an attenuation
network. This attenuation network has to be adjusted to the oscil-
loscope input circuitry, to guarantee frequency independency. This
10 Chapter 3
is called the low frequency compensation. Each time a probe is
used on an other channel or an other oscilloscope, the probe must
be adjusted.
Therefore the probe is equiped with a setscrew, with which the
parallel capacity of the attenuation network can be altered. To
adjust the probe, switch the probe to the x10 and attach the probe
to a 1 kHz square wave signal. Then adjust the probe for a square
front corner on the square wave displayed. See also the following
illustrations.
Figure 3.6: correct
Figure 3.7: under compensated
Figure 3.8: over compensated
Introduction 11
12 Chapter 3
Driver installation 4
Before connecting the Handyscope HS3 to the computer, the
drivers need to be installed.
4.1 Introduction
To operate a Handyscope HS3, a driver is required to interface
between the measurement software and the instrument. This driver
takes care of the low level communication between the computer
and the instrument, through USB. When the driver is not installed,
or an old, no longer compatible version of the driver is installed, the
software will not be able to operate the Handyscope HS3 properly
or even detect it at all.
The installation of the USB driver is done in a few steps. Firstly,
the driver has to be pre-installed by the driver setup program. This
makes sure that all required files are located where Windows can
find them. When the instrument is plugged in, Windows will detect
new hardware and install the required drivers.
4.2 Where to find the driver setup
The driver setup program and measurement software can be found
in the download section on TiePie engineering’s website and on the
CD-ROM that came with the instrument. It is recommended to
install the latest version of the software and USB driver from the
website. This will guarantee the latest features are included.
4.3 Executing the installation utility
To start the driver installation, execute the downloaded driver
setup program, or the one on the CD-ROM that came with the
instrument. The driver install utility can be used for a first time
Driver installation 13
installation of a driver on a system and also to update an existing
driver.
The screen shots in this description may differ from the ones
displayed on your computer, depending on the Windows version.
Figure 4.1: Driver install: step 1
When drivers were already installed, the install utility will re-
move them before installing the new driver. To remove the old
driver successfully, it is essential that the Handyscope HS3 is
disconnected from the computer prior to starting the driver install
utility. When the Handyscope HS3 is used with an external power
supply, this must be disconnected too.
14 Chapter 4
Figure 4.2: Driver install: step 2
When the instrument is still connected, the driver install utility
will recognize it and report this. You will be asked to continue
anyway.
Figure 4.3: Driver install: Instrument is still connected
Clicking ”No”will bring back the previous screen. The instru-
ment should now be disconnected. Then the removal of the existing
driver can be continued by clicking ”Next”.
Clicking ”Yes”will ignore the fact that the instrument is still
connected and continue removal of the old driver. This option is
not recommended, as removal may fail, after which installation of
the new driver may fail as well.
When no existing driver was found or the existing driver is
removed, the location for the pre-installation of the new driver can
be selected.
Driver installation 15
Figure 4.4: Driver install: step 3
On Windows XP and newer, the installation may inform about
the drivers not being ”Windows Logo Tested”. The driver is not
causing any danger for your system and can be safely installed.
Please ignore this warning and continue the installation.
Figure 4.5: Driver install: step 4
The driver install utility now has enough information and can
install the drivers. Clicking ”Install”will remove existing drivers
and install the new driver. A remove entry for the new driver is
added to the software applet in the Windows control panel.
16 Chapter 4
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