This powerful high speed USB oscilloscope combines fast sampling up to 500 MS/s with high resolutions of 12, 14 and 16 bit, a large memory of 64 MSamples and an extremely accurate built-in 40 MHz 14 bit Constant Data Size (CDS) arbitrary waveform generator with 24 V peak to peak output, generating true form signals. The oscilloscope supports continuous streaming measurements up to 20 MS/s and can be synchronized with other oscilloscopes using the CMI interface to form a multi channel combined instrument with synchronized timebase. The CMI interface is available by default on the Handyscope HS5. Optionally, the Handyscope HS5 can be delivered with SureConnect connection test and resistance measurement on each channel. The flexibility and quality that the Handyscope HS5 offers is unparalleled by any other oscilloscope and function generator in its class.
This best in class High Resolution USB oscilloscope with integrated Arbitrary Waveform Generator gives the best specifications available in the industry, for a limited budget. The flexibility and quality that the Handyscope HS5 offers is unparalleled by any other oscilloscope and function generator in its class.
Key specifications:
Oscilloscope / Spectrum analyzer / Multimeter / Data logger |
---|
14 bit (0.006 %) resolution (16 bit enhanced resolution) |
500 MS/s sampling |
250 MHz bandwidth |
20 MS/s, 14 bit continuous streaming |
32 MSamples memory per channel |
0.25 % DC vertical accuracy, 0.1 % typical |
1 ppm time base accuracy |
Arbitrary Waveform Generator |
---|
1 µHz to 40 MHz sine, square, triangular and arbitrary waveforms |
240 MS/s, 14 bit |
64 MSamples arbitrary waveform memory |
-12 to 12 V output (24 Vpp) |
1 ppm time base accuracy |
Spurious (non harmonic) < -85 dB |
8 ns rise and fall time |
The Handyscope HS5 can be synchronized with other oscilloscopes using the CMI interface to form a multi channel combined instrument with synchronized timebase. The CMI interface is available by default on the Handyscope HS5.
Optionally available: SureConnect connection test: real time probe connection verification while measuring and fast and accurate resistance measurement on all channels.
The Handyscope HS5 is available in 5 different base models:
Order code | Max. sampling speed | Max. streaming speed | Max. signal frequency AWG |
---|---|---|---|
HS5-540 | 500 MS/s | 20 MS/s | 40 MHz |
HS5-530 | 500 MS/s | 20 MS/s | 30 MHz |
HS5-220 | 200 MS/s | 10 MS/s | 20 MHz |
HS5-110 | 100 MS/s | 5 MS/s | 10 MHz |
HS5-055 | 50 MS/s | 2 MS/s | 5 MHz |
Available options for the Handyscope HS5 are:
The Handyscope HS5 models come with the following items:
Amount | Item |
---|---|
1 | Handyscope HS5 |
2 | Oscilloscope Probe 1:1-1:10 - HP-9250 |
1 | Handyscope power supply |
1 | External power cable (USB) |
1 | CD-ROM with Multi Channel oscilloscope software and drivers |
1 | Instrument manual |
1 | Software manual |
With the Multi Channel oscilloscope software, the world's most sophisticated measuring software, the Handyscope HS5 can be used as: High Resolution USB Oscilloscope, multimeter, spectrum analyzer, data logger/transient recorder, protocol analyzer and Arbitrary Waveform Generator. This powerful and compact measuring instrument can solve almost any measurement problem.
The Handyscope HS5 measures with high resolutions of 14 and 16 bit. A signal measured with the Handyscope HS5 therefore has 256 times more resolution than most standalone oscilloscopes, which usually have a low resolution of 8 or 9 bit. The high resolution of the Handyscope HS5 precision oscilloscope allows for measuring signals with more accuracy, because the quantization error is much lower.
The input circuit of the Handyscope HS5 has a high accuracy of 0.25 % of the full scale input range, where most standalone oscilloscopes have an accuracy of 2 - 3 % of the full scale range.
To display a signal measured with the Handyscope HS5 High Resolution oscilloscope at the same level of detail as the standalone oscilloscope, the display can be 256 times larger. Viewing the signals on a 24" monitor immediately gives a very detailed impression of the signal. The smallest deviations are very well visible and because of the high resolution, it is still possible to zoom in and reveal additional details.
Figure 1: Handyscope HS5 high visible accuracy compared to competition.
Shown in figure 1 are two displays, both showing a measurement of the same signal. The left display size corresponds to a size comparable to a standalone oscilloscope; at 8 bit resolution, zooming will not reveal more details. The right display corresponds to a maximized window on a standard PC screen; at 14 bit resolution, zooming will still reveal more details.
The high resolution and high accuracy of the Handyscope HS5 and the unlimited zoom of the Multi Channel oscilloscope software allow to zoom in to mV levels. Figure 2 shows a measurement of a 2 mV sine wave made in the 200 mV input range, which is then zoomed in to view the signal at an 8 mV scale.
Figure 2: Zoomed in to get an 8 mV input scale.
With a time base accuracy of 1 ppm, frequency and timing can be measured very accurately. The time base of the Handyscope HS5 is 25 to 100 times more accurate than comparable instruments of the competition.
Coupling multiple instruments to a large combined instrument does not affect the time base accuracy. The timing deviation between the coupled instruments is 0 ppm.
The Handyscope HS5 is the first High Resolution USB oscilloscope with built-in 30 MHz low distortion function generator. The built-in Arbitrary Waveform Generator uses CDS signal synthesis technology, developed by TiePie engineering, resulting in the best signal fidelity in its class, generating the true form of your signals. With spurious distortion as low as -85 dB at 100 kHz signal frequency, a very flat amplitude spectrum and a rise time of 8 ns, the low distortion function generator creates signals that approach perfection.
Figure 3: Handyscope HS5 function generator sine wave with extremely low spurious.
Combined with an output voltage of 24 Vpp, a resolution of 14 bit at 240 MS/s and a waveform buffer of 64 MSamples, this makes the Handyscope HS5 Arbitrary waveform generator truly a high quality low distortion function generator. Standard signal shapes like sine wave, square wave, triangle, pulse, DC and noise are available. When a custom signal shape is required, this can be created in the 64 million samples large memory or by loading a previously measured signal from the oscilloscope.
The Handyscope HS5 supports continuous streaming measurements with a speed up to 20 MS/s, which makes it possible to measure endlessly, without any memory limits. Data can be stored directly to disk using the multi channel integrated data logger, which is only limited by the amount of available disk space.
During recording, the measured signal can be viewed and analyzed in real time. The high continuous sampling frequency is high enough to log serial communication signals such as CAN bus. Using streaming measuring, difficult problems can easily be measured, traced back and analyzed.
The Handyscope HS5 is equipped with a sophisticated CMI synchronization bus, allowing to connect multiple Handyscope HS5s to each other by means of coupling cables, to use them as a combined instrument. All instruments will measure at the same sample frequency (0 ppm deviation!) The maximum number of instruments is only limited by the number available USB ports.
Combining the instruments is fully automatic. When the Multi Channel oscilloscope software is started, the Handyscope HS5s coupled with TP-C50H Coupling cables are identified and automatically combined to a larger instrument. The synchronization bus is automatically terminated at both ends with the correct impedance, so there is no need to manually place terminators. This unique possibility to create e.g. an 8 channel instrument is only available with the Handyscope HS5 and no other USB oscilloscope.
With its high resolution of 16 bits, the Handyscope HS5 can be used as a comprehensive and accurate high performance digital multimeter, with measurements like RMS, peak-peak, Max, Min, Mean, Variance, Standard deviation, Frequency, Duty cycle, Crest factor, Rise time, Fall time, dBm, etc. Both numerical and gauge displays are available in the multimeter. The stable and 1 ppm accurate time base of the Handyscope HS5 enable very accurate frequency and time measurements. These qualities make an extra multimeter or frequency counter redundant and make the Handyscope HS5 unique in its class.
You can make as many high performance multimeter displays as you want, in any size and different layouts.
The Handyscope HS5 definitely brings an end to the idea that spectrum analyzers are expensive, hard to control and difficult to understand. The large flexibility of the spectrum analyzer makes it not just suitable for measuring high frequency signals of transmitters and receivers, but also for viewing signals that are invisible in the time domain display of an oscilloscope.
When troubleshooting, usually an oscilloscope is used, but when the amplitude of the signal of interest is small, it may be badly visible on an oscilloscope and drown in noise. When viewed with a spectrum analyzer in the frequency domain however, all spectral components of the signal and their magnitude can be clearly observed.
Figure 4: While invisible in the time domain, a small signal is clearly visible in the spectrum.
Analyzing signals in the frequency domain is very useful for example when measuring disturbances caused by a switched power supply. The switching signal of the switched mode power supply can be measured by holding the probe close to the inductor of the power supply and can be stored as a reference signal. When this reference signal is displayed besides a live spectrum during measuring, the switching signal is easily distinguished from other signals in the device under test. When taking measures to reduce the unwanted influence of the power supply, the suppression can be observed directly with the Handyscope HS5 USB spectrum analyzer.
This method of troubleshooting in the frequency domain is only possible (and unique for the Handyscope HS5) because of the Handyscope HS5's unique combination of features:
The high resolution of the Handyscope HS5 (14 and 16 bit) and its large large record length of 32 MSamples make it possible to perform a spectral analysis with up to 16 million frequency components with a very high resolution in the frequency domain. A spectrum with a dynamic range of more than 120 dB can be measured, which makes the Handyscope HS5 unique in its class.
When measuring at high sample rates, a long record length/large memory is necessary to be able to record a complete signal in the acquisition buffer. Where most oscilloscopes have 2.5 kSamples or 100 kSamples memory, the Handyscope HS5 has 32 MSamples memory per channel. This gives the user 300 to 10000 times more memory. An advantage of a large memory is that once-only fast phenomena can be captured completely. For example complete serial communications, like CAN bus signals, can be measured all in one record to be reviewed and analyzed afterwards.
The large memory results in the advantage of a large dynamic range in the USB spectrum analyzer, which enables troubleshooting in the frequency domain.
The unlimited superzoom feature of the Handyscope HS5 allows to zoom in to individual samples, no matter what record length is used.
Figure 5: The same signal viewed simultaneously with several zoom factors up to 30000
Figure 1 shows the same signal four times with different zooming factors. The lower right graph shows just 0.01 ms of the total 300 ms, a zoom factor of 30000 and still provides enough detail for accurate signal analysis.
The SureConnect connection test feature of the Handyscope HS5 tells you immediately whether your test probe or clip actually makes electrical contact or not. No more doubt whether your probe doesn't make contact or there really is no signal.
This is useful when surfaces are oxidized and your probe cannot get a good electrical contact. Simply activate the SureConnect and you know whether there is contact or not. Also when back probing connectors in confined places, SureConnect immediately shows whether the probes make contact or not.
SureConnect is optionally available on the Handyscope HS5.
The various serial protocol analyzers of the Handyscope HS5 can be used to analyze and debug serial data buses. The data is displayed in an elaborate table with information on the serial data. Locating "wrong" data packets has become very easy with a protocol analyzer. For each developer or service technician this is a welcome option. Protocol analyzers for CAN bus data, J1939, RS232, I2C communication and various other serial data communications are available with the Handyscope HS5 protocol analyzer.
Figure 6: Decoded CAN data from a measurement of both CAN-low and CAN-high.
The High Resolution USB oscilloscope and the arbitrary waveform generator in the Handyscope HS5 can be easily synchronized by setting the trigger source of the oscilloscope to one or more generator trigger events: start, stop and new period. This synchronization makes it possible for example to perform a sweep, and directly measure the frequency spectrum. In the shown measurement, a sweep from 1 MHz to 7 MHz is generated and injected in a resonance filter of 4 MHz of which the output is measured. As this is a real time synchronized scope with AWG measurement, a drop in resonance frequency is immediately visible when the resonance filter is heated.
Figure 7: HS5 oscilloscope measurement of a resonance filter fed with a 1 MHz to 7 MHz sweep from a Handyscope HS5 AWG.
The Multi Channel oscilloscope software for the Handyscope HS5 offers a large variety of mathematical operations like adding, subtracting, multiplying, dividing, integrating, differentiating, determining the square root, determining the logarithm, etc. These mathematical operations are available in the form of I/Os, also called processing blocks, and can be used to process the measured signals and reference signals.
Besides the basic mathematical operations, there are also several processing blocks to perform other, more complex mathematical operations on the data, like determining minimum or maximum values, limiting to specified range, averaging, filtering, applying gain and offset, resampling etc.
Icon | Operation | Icon | Operation |
---|---|---|---|
Gain/Offset | Average | ||
Add/Subtract | LowPass | ||
Multiply/Divide | MinMax | ||
SQRT | Limiter | ||
ABS | Resampler | ||
Differentiate | DataCollector | ||
Integrate | FFT | ||
Log | DutyCycle |
Combining these mathematical processing blocks gives unrivaled possibilities in constructing complex mathematical operations to analyze your measurements thoroughly and obtain all the information you need from your data. The results of the mathematical operations can be displayed in one or more graphs, can be displayed in numeric displays, in tables and can be written to disk in various common file formats.
Figure 8: Using processing blocks to calculate the area of an XY graph.
Figure 1 shows a measurement performed with the Handyscope HS5. Processing block are used to determine the area of an XY graph, using multiplying, integrating and differentiating I/Os. The area is indicated in the value window: 16 V2.
The tables below show detailed specifications of the Handyscope HS5. Jump to acquisition specifications, trigger specifications, function generator specifications or general specifications.
Acquisition system | |
---|---|
Number of input channels | 2 analog |
CH1, CH2 | BNC |
Type | Single ended |
Resolution | 8, 12, 14, 16 bit user selectable |
DC Accuracy | 0.25 % (0.1 % typical) of full scale ± 1 LSB |
Ranges | ±200 mV to ±80 V full scale |
Coupling | AC/DC |
Impedance | 1 MOhm / 25 pF ± 1 % |
Maximum voltage | 200 V (DC + AC peak < 10 kHz) |
Maximum voltage 1:10 probe | 600 V (DC + AC peak < 10 kHz) |
Bandwidth (-3dB) | at 75 % of full scale input |
Ch1 | 250 MHz |
Ch2 | 100 MHz |
AC coupling cut off frequency (-3dB) | ±1.5 Hz |
SureConnect | Optionally available (option S) |
Maximum voltage on connection | 200 V (DC + AC peak < 10 kHz) |
Resistance measurement | Optionally available (option S) |
Ranges | 100 Ohm to 2 MOhm full scale in 1-2-5 sequence |
Accuracy | 1 % of full scale |
Response time (to 95%) | < 10 µs |
Maximum sampling rate | Depending on model |
Model HS5-540 | |
8/12 bit, measuring one channel | 500 MS/s |
8/12 bit, measuring two channels | 200 MS/s |
14 bit | 100 MS/s |
16 bit | 6.25 MS/s |
Model HS5-530 | |
8/12 bit, measuring one channel | 500 MS/s |
8/12 bit, measuring two channels | 200 MS/s |
14 bit | 100 MS/s |
16 bit | 6.25 MS/s |
Model HS5-220 | |
8/12 bit, measuring one channel | 200 MS/s |
8/12 bit, measuring two channels | 100 MS/s |
14 bit | 50 MS/s |
16 bit | 3.125 MS/s |
Model HS5-110 | |
8/12 bit, measuring one channel | 100 MS/s |
8/12 bit, measuring two channels | 50 MS/s |
14 bit | 20 MS/s |
16 bit | 1.25 MS/s |
Model HS5-055 | |
8/12 bit, measuring one channel | 50 MS/s |
8/12 bit, measuring two channels | 20 MS/s |
14 bit | 10 MS/s |
16 bit | 625 kS/s |
Maximum streaming rate | Depending on Handyscope HS5 model and computer 1 |
Model HS5-540 | |
8 bit, measuring one channel | 40 MS/s |
8 bit, measuring two channels | 20 MS/s |
12/14 bit, measuring one channel | 20 MS/s |
12/14 bit, measuring two channels | 10 MS/s |
16 bit | 6.25 MS/s |
Model HS5-530 | |
8 bit, measuring one channel | 40 MS/s |
8 bit, measuring two channels | 20 MS/s |
12/14 bit, measuring one channel | 20 MS/s |
12/14 bit, measuring two channels | 10 MS/s |
16 bit | 6.25 MS/s |
Model HS5-220 | |
8 bit, measuring one channel | 20 MS/s |
8 bit, measuring two channels | 10 MS/s |
12/14 bit, measuring one channel | 10 MS/s |
12/14 bit, measuring two channels | 5 MS/s |
16 bit | 3.125 MS/s |
Model HS5-110 | |
8 bit, measuring one channel | 10 MS/s |
8 bit, measuring two channels | 5 MS/s |
12/14 bit, measuring one channel | 5 MS/s |
12/14 bit, measuring two channels | 2 MS/s |
16 bit | 1.25 MS/s |
Model HS5-055 | |
8 bit, measuring one channel | 4 MS/s |
8 bit, measuring two channels | 2 MS/s |
12/14 bit, measuring one channel | 2 MS/s |
12/14 bit, measuring two channels | 1 MS/s |
16 bit | 625 kS/s |
Sampling clock source | |
Internal | TCXO |
Accuracy | ± 0.0001 % |
Stability | ± 1 ppm over 0°C to 55°C |
Time base aging | ±1 ppm/year |
External | LVDS, on auxiliary connectors |
Input range | 10 MHz |
Memory | |
Standard model | 128 KiSamples per channel |
XM option |
32 MSamples per channel 64 MSamples measuring one channel |
Trigger | |
System | Digital, 2 levels |
Source | CH1, CH2, OR, digital external, generator start, generator new period, generator stop |
Trigger modes | Rising edge, falling edge, any edge, inside window, outside window, enter window, exit window, pulse width |
Level adjustment | 0 to 100 % of full scale |
Hysteresis adjustment | 0 to 100 % of full scale |
Resolution | 0.006 % (14, 16 bits) / 0.025% (12 bits) |
Pre trigger | 0 to 64 MSamples measuring 1 channel, 0 to 32 MSamples measuring 2 channels, 1 sample resolution |
Post trigger | 0 to 64 MSamples measuring 1 channel, 0 to 32 MSamples measuring 2 channels, 1 sample resolution |
Trigger hold-off | 0 to 63 MSamples, 1 sample resolution |
Trigger delay | 0 to 16 GSamples, 1 sample resolution |
Segmented trigger | Available via LibTiePie SDK |
Maximum number of segments | 1024 |
Minimum segment length | 1 sample |
Maximum segment length |
32 M / number of segments 64 M / number of segments measuring one channel |
Trigger rearm time | Sample frequency dependent, < 700 ns on highest sample frequency |
Digital external trigger | |
Input | Extension connector pins 1, 2 and 3 |
Range | 0 to 2.5 V (TTL) |
Coupling | DC |
Jitter | Depending on source and sample frequency |
Source = channel | ≤ 1 sample |
Source = external or generator | |
Sample frequency = 500 MS/s | ≤ 8 samples |
Sample frequency < 500 MS/s | ≤ 4 samples |
Sample frequency ≤ 100 MS/s | ≤ 1 sample |
Arbitrary Waveform Generator (independent from acquisition system) | |
---|---|
Waveforms | |
Standard | Sine, square, triangle, pulse, noise, DC |
Built-in arbitrary | Exponential rise and fall, sin(x)/x, cardiac, haversine, lorentz, d-lorentz |
Signal characteristics | |
Sine | |
Frequency range | Depending on model |
Model HS5-540 | 1 µHz to 40 MHz |
Model HS5-530 | 1 µHz to 30 MHz |
Model HS5-220 | 1 µHz to 20 MHz |
Model HS5-110 | 1 µHz to 10 MHz |
Model HS5-055 | 1 µHz to 5 MHz |
Amplitude flatness | Relative to 1 kHz |
< 100 kHz | ±0.1 dB |
< 5 MHz | ±0.15 dB |
< 20 MHz | ±0.3 dB |
< 30 MHz | ±0.4 dB |
< 40 MHz | ±1 dB |
Spurious (non harmonic) | |
< 100 kHz | -75 dBc |
100 kHz to 1 MHz | -70 dBc |
1 MHz to 10 MHz | -60 dBc |
10 MHz to 15 MHz | -55 dBc |
15 MHz to 20 MHz | -45 dBc |
20 MHz to 30 MHz | -35 dBc |
30 MHz to 40 MHz | -30 dBc |
Square | |
Frequency range | Depending on model |
Model HS5-540 | 1 µHz to 30 MHz, above 30 MHz not specified |
Model HS5-530 | 1 µHz to 30 MHz |
Model HS5-220 | 1 µHz to 20 MHz |
Model HS5-110 | 1 µHz to 10 MHz |
Model HS5-055 | 1 µHz to 5 MHz |
Rise/fall time | < 8 ns |
Overshoot | < 1 % |
Variable duty cycle | 0.01 % to 99.99 % |
Asymmetry | 0 % of period + 5 ns (@ 50 % Duty cycle) |
Jitter (RMS) | < 50 ps |
Triangle | |
Frequency range | Depending on model |
Model HS5-540 | 1 µHz to 30 MHz, above 30 MHz not specified |
Model HS5-530 | 1 µHz to 30 MHz |
Model HS5-220 | 1 µHz to 20 MHz |
Model HS5-110 | 1 µHz to 10 MHz |
Model HS5-055 | 1 µHz to 5 MHz |
Nonlinearity (of peak output) | < 0.01 % |
Symmetry | 0 % - 100 %, 0.1 % steps |
Pulse | |
Period | 100 ns to 1000 s |
Pulse width | 15 ns to 1000 s |
Variable edge time | 8 ns to 1 s |
Overshoot | < 1 % |
Jitter (rms) | < 50 ps |
Noise | |
Bandwidth (typical) | 30 MHz |
Arbitrary | |
Frequency | Depending on model |
Model HS5-540 | 0.4 nHz to 30 MHz |
Model HS5-530 | 0.4 nHz to 30 MHz |
Model HS5-220 | 0.4 nHz to 20 MHz |
Model HS5-110 | 0.4 nHz to 10 MHz |
Model HS5-055 | 0.4 nHz to 5 MHz |
Length | |
Standard model | 1 to 256 KiSamples |
XM option | 1 to 64 MiSamples |
Maximum sample rate | Depending on model |
Model HS5-540 | 240 MS/s |
Model HS5-530 | 240 MS/s |
Model HS5-220 | 200 MS/s |
Model HS5-110 | 100 MS/s |
Model HS5-055 | 50 MS/s |
Rise/Fall time | < 8 ns |
Nonlinearity (of peak output) | < 0.01 % |
Settling time | < 8 ns to 10 % final value |
Jitter (RMS) | < 50 ps |
Common characteristics | |
Number of output channels | 1 analog, BNC |
DAC resolution | 14 bit |
Output range | -12 to +12 V (24 Vpp) at open circuit |
Amplitude | |
Range | 0.12 V (0.24 Vpp), 1.2 V (2.4 Vpp), 12 V (24 Vpp) at open circuit |
Resolution | 12 bit |
Accuracy | 0.4 % of range |
DC offset | |
Range | -12 to +12 V at open circuit |
Resolution | 12 bit |
Accuracy | 0.4 % of range |
Noise level | |
0.12 V range | 900 µVRMS |
1.2 V range | 1.3 mVRMS |
12 V range | 1.5 mVRMS |
Coupling | DC |
Impedance | 50 Ohm |
Overload protection | Output turns off automatically when overload is applied. Instrument will tolerate a short circuit to ground indefinitely. |
Burst | |
Waveforms | Sine, square, triangle, noise, arbitrary |
Count | 1 to 65535 |
Trigger | Software, external |
Sweep | Available on models with extended memory option XM |
Waveforms | Sine, square, triangle |
Type | Linear, logarithmic |
Direction | Up, down |
Trigger | Software, external |
Modulation | |
AM | |
Carrier waveforms | Sine, square, triangular |
Modulating waveforms | Sine, square, triangular, noise, arbitrary |
Modulating frequency | 2 mHz to 20 MHz |
Depth | 0.0 % to 100 % |
Source | Internal |
FM | |
Carrier waveforms | Sine, square, triangular |
Modulating waveforms | Sine, square, triangular, noise, arbitrary |
Modulating frequency | 2 mHz to 20 MHz |
Peak deviation | DC to 20 MHz |
Source | Internal |
FSK | |
Carrier waveforms | Sine, square, triangular |
Modulating waveforms | 50 % duty cycle square |
Modulating frequency | 2 mHz to 20 MHz |
Peak deviation | 1 µHz to 20 MHz |
Source | Internal |
System characteristics | |
System | Constant Data Size |
Memory | |
Standard model | 256 KiSamples |
Option XM | 64 MiSamples |
Operating modes | Continuous, triggered, gated |
Maximum sampling rate | Depending on model |
Model HS5-530 | 240 MS/s |
Model HS5-220 | 200 MS/s |
Model HS5-110 | 100 MS/s |
Model HS5-055 | 50 MS/s |
Sampling source | Internal TCXO |
Accuracy | ±0.0001 % |
Stability | ±1 ppm over 0°C to +55°C |
Time base aging | ±1 ppm/year |
Multi-instrument synchronization | |
Maximum number of instruments | Limited by number of available USB ports |
Synchronization accuracy | 0 ppm |
Interface | |
Interface |
USB 2.0 High Speed (480 Mbit/s); (USB 1.1 Full Speed (12 Mbit/s) and USB 3.0 compatible) |
Power Requirements | |
Power | From USB port or external input |
Consumption | 5 VDC 2000 mA max |
External power | From second USB port or power adapter |
Physical | |
Instrument height | 25 mm (1 inch) |
Instrument length | 170 mm (6.7 inch) |
Instrument width | 140 mm (5.2 inch) |
Weight | 430 g (15 ounce) |
USB cord length | 1.8 m (70 inch) |
I/O connectors | |
Channel 1, 2 | BNC |
Generator | BNC |
USB | Fixed cable with USB 2.0 and USB 1.1 type A connector, 1.8 m |
Extension connector | D-sub 9 pins female |
Power | 3.5 mm power socket |
Auxiliary I/O connectors | 2 x HDMI type C socket |
System requirements | |
PC I/O connection | USB 1.1, USB 2.0 or newer |
Operating system |
Windows XP/Vista/7/8/10, 32 and 64 bits Linux (via LibTiePie SDK) |
Environmental conditions | |
Operating | |
Ambient temperature | 0 to 55°C |
Relative humidity | 10 % to 90 %, non condensing |
Storage | |
Ambient temperature | -20 to 70°C |
Relative humidity | 5 % to 95 %, non condensing |
Certifications and Compliances | |
CE mark compliance | Yes |
RoHS | Yes |
EN 55011:2009/A1:2010 | Yes |
EN 55022:2006/A1:2007 | Yes |
EN 61000-6-1:2007 | Yes |
EN 61000-6-3:2007 | Yes |
Package contents | |
Instrument | Handyscope HS5 |
Oscilloscope probes | 2 x Oscilloscope Probe 1:1-1:10 - HP-9250 |
Accessories | Handyscope power supply, external power cable for USB port |
Software | for Windows 2000/XP/Vista/7/8/10 on CD |
Drivers | for Windows 2000/XP/Vista/7/8/10 on CD |
Manuals |
instrument manual and software user's manuals color printed and digital on CD |
Customer service | |
TiePie engineering instruments are designed, manufactured and tested to provide high reliability. In the unlikely event you experience difficulties, the TiePie engineering instruments are fully warranted for three years. | |
This warranty includes |
All parts and labor (excluding probes) No charge for return shipping Long-term 7 year support Upgrade to the latest software at no charge |
Optionally available | Extension to five year warranty |
Several accessories are available for use with the Handyscope HS5. The most common related accessories, such as oscilloscope probes and current clamps are listed here. Refer to the products page to find all TiePie products.
For more information about the Handyscope HS5, refer to the following articles. Several key aspects of the Handyscope HS5 are treated, such as the outstanding signal quality of the Handyscope HS5 CDS arbitrary waveform generator.
The Handyscope HS5 is available with different combinations of maximum sampling speed, memory depth, maximum function generator signal frequency, SureConnect and extended 5 year warranty. All models are listed below and can be ordered directly from stock.
Order code | Max. sampling speed | Max. streaming speed | Max. signal frequency AWG | Memory | SureConnect | Warranty |
---|---|---|---|---|---|---|
EJH5-540XMS-W5 | 500 MS/s | 20 MS/s | 40 MHz | 32 MiS | • | 5 years |
EJH5-530XMS-W5 | 500 MS/s | 20 MS/s | 30 MHz | 32 MiS | • | 5 years |
EJH5-220XMS-W5 | 200 MS/s | 10 MS/s | 20 MHz | 32 MiS | • | 5 years |
EJH5-110XMS-W5 | 100 MS/s | 5 MS/s | 10 MHz | 32 MiS | • | 5 years |
EJH5-055XMS-W5 | 50 MS/s | 2 MS/s | 5 MHz | 32 MiS | • | 5 years |
EJH5-540XMS | 500 MS/s | 20 MS/s | 40 MHz | 32 MiS | • | 3 years |
EJH5-530XMS | 500 MS/s | 20 MS/s | 30 MHz | 32 MiS | • | 3 years |
EJH5-220XMS | 200 MS/s | 10 MS/s | 20 MHz | 32 MiS | • | 3 years |
EJH5-110XMS | 100 MS/s | 5 MS/s | 10 MHz | 32 MiS | • | 3 years |
EJH5-055XMS | 50 MS/s | 2 MS/s | 5 MHz | 32 MiS | • | 3 years |
EJH5-540S-W5 | 500 MS/s | 20 MS/s | 40 MHz | 128 KiS | • | 5 years |
EJH5-530S-W5 | 500 MS/s | 20 MS/s | 30 MHz | 128 KiS | • | 5 years |
EJH5-220S-W5 | 200 MS/s | 10 MS/s | 20 MHz | 128 KiS | • | 5 years |
EJH5-110S-W5 | 100 MS/s | 5 MS/s | 10 MHz | 128 KiS | • | 5 years |
EJH5-055S-W5 | 50 MS/s | 2 MS/s | 5 MHz | 128 KiS | • | 5 years |
EJH5-540S | 500 MS/s | 20 MS/s | 40 MHz | 128 KiS | • | 3 years |
EJH5-530S | 500 MS/s | 20 MS/s | 30 MHz | 128 KiS | • | 3 years |
EJH5-220S | 200 MS/s | 10 MS/s | 20 MHz | 128 KiS | • | 3 years |
EJH5-110S | 100 MS/s | 5 MS/s | 10 MHz | 128 KiS | • | 3 years |
EJH5-055S | 50 MS/s | 2 MS/s | 5 MHz | 128 KiS | • | 3 years |
EJH5-540XM-W5 | 500 MS/s | 20 MS/s | 40 MHz | 32 MiS | 5 years | |
EJH5-530XM-W5 | 500 MS/s | 20 MS/s | 30 MHz | 32 MiS | 5 years | |
EJH5-220XM-W5 | 200 MS/s | 10 MS/s | 20 MHz | 32 MiS | 5 years | |
EJH5-110XM-W5 | 100 MS/s | 5 MS/s | 10 MHz | 32 MiS | 5 years | |
EJH5-055XM-W5 | 50 MS/s | 2 MS/s | 5 MHz | 32 MiS | 5 years | |
EJH5-540XM | 500 MS/s | 20 MS/s | 40 MHz | 32 MiS | 3 years | |
EJH5-530XM | 500 MS/s | 20 MS/s | 30 MHz | 32 MiS | 3 years | |
EJH5-220XM | 200 MS/s | 10 MS/s | 20 MHz | 32 MiS | 3 years | |
EJH5-110XM | 100 MS/s | 5 MS/s | 10 MHz | 32 MiS | 3 years | |
EJH5-055XM | 50 MS/s | 2 MS/s | 5 MHz | 32 MiS | 3 years | |
EJH5-540-W5 | 500 MS/s | 20 MS/s | 40 MHz | 128 KiS | 5 years | |
EJH5-530-W5 | 500 MS/s | 20 MS/s | 30 MHz | 128 KiS | 5 years | |
EJH5-220-W5 | 200 MS/s | 10 MS/s | 20 MHz | 128 KiS | 5 years | |
EJH5-110-W5 | 100 MS/s | 5 MS/s | 10 MHz | 128 KiS | 5 years | |
EJH5-055-W5 | 50 MS/s | 2 MS/s | 5 MHz | 128 KiS | 5 years | |
EJH5-540 | 500 MS/s | 20 MS/s | 40 MHz | 128 KiS | 3 years | |
EJH5-530 | 500 MS/s | 20 MS/s | 30 MHz | 128 KiS | 3 years | |
EJH5-220 | 200 MS/s | 10 MS/s | 20 MHz | 128 KiS | 3 years | |
EJH5-110 | 100 MS/s | 5 MS/s | 10 MHz | 128 KiS | 3 years | |
EJH5-055 | 50 MS/s | 2 MS/s | 5 MHz | 128 KiS | 3 years |