400 - 6112, 2-Ch, 250kS/s, AnyWave Control Unit

Gallery 400 - 6112, 2-Ch, 250kS/s, AnyWave Control Unit

400 - 6112, 2-Ch, 250kS/s, AnyWave Control Unit

WaveMaster + AnyWave

BOLAB WaveMaster software and the BOLAB AnyWave control unit allow the control of power supplies as well as 4 quadrant amplifiers via the analog interfaces.

The powerful and easy-to-use BOLAB WaveMaster software is unique in the world. Without any knowledge in software development, designing ordinary and complex waveforms is very easy. A graphic waveform editor allows the generation

of individual curves in no time. Also, with tabular input, all types of waveforms can be produced instantly.

PARTNER:

BOLAB SYSTEMS GMBH

MARKETS:

TEST STANDARDS:

Data Sheet

SPECIFICATIONS

BOLAB WaveMaster Software

&

BOLAB AnyWave Control Unit

Generate Arbitrary Waveforms with standard power supplies and 4 quadrant amplifiers

BOLAB AnyWave Control Units

Up to 2,8 MS/s sampling rate (approx. 330ns resolution)
2 synchronous output channels
16-bit resolution
Analog input channels
Almost endless data streams for waveform generation
No limitation as is the case with function generators
Trigger inputs / outputs for real-time actions (starting waveform / activating measurement)
2 Channel Arbitrary Waveform Generation
Live Data Acquisition
Graphic / Tabular Waveform
Design Importing Real Waveforms (e.g. from Oscilloscopes)
Complete Standard Waveform Libraries
Protocol Report with Recorded Data
DLLs for Python, LabView, CANoe, etc.

Type	Analog Output Sampling rate	Number of Analogue outputs	Analogue Input Sampling Rate
400 - 6212	250 kS/s	2	25 kS/s
400 - 6361	2,86 MS/S¹⁾	2	300 kS/s

1) When using one channel/waveform

General

The BOLAB AnyWave control unit controls all kinds of power supplies as well as 4 quadrant amplifiers via analog interfaces. It has two analog outputs to provide two waveforms synchronously to different power supplies / 4 quadrant amplifiers. Sampling rates of 2,8 MS/s, 16 bit and 250 kS/s, 16-bit units are available.

BOLAB’s AnyWave control unit provides a bandwidth of up to 300 kHz very easily.

Its internal memory is handled by a double buffer mode which provides endless data streams without any interruption! Waveforms of almost infinite lengths can be simulated. This provides the most advantage in comparison to any function generator solutions which are limited in their memory and speed due to their limited arbitrary function!

BOLAB WaveMaster Software

Easy to use graphic waveform editor and tabular input
Reference waveform and data acquisition with live graphics
Including standard libraries for
- LV124, VW 80000
- LV148, VDA 320
- LV123, VW 80300
- GMW
- JLR
Command library to build-up or for integration into automated test systems such as:
- LabView
- Vector CANoe (CAPL)
- Vector via C# real time!
- Python
- C#
- C++
- ANSI C
- MATHLAB
Simulation of imported oscilloscope signals
Protocol report with reference data and measurement

General

BOLAB WaveMaster software and the BOLAB AnyWave control unit allow the control of power supplies as well as 4 quadrant amplifiers via the analog interfaces.

The powerful and easy-to-use BOLAB WaveMaster software is unique in the world. Without any knowledge in software development, designing ordinary and complex waveforms is very easy.

A graphic waveform editor allows the generation of individual curves in no time. Also, with tabular input, all types of waveforms can be produced instantly.

The simplicity of how fast oscilloscope data signals can be imported is exceptional. Reading ASCII and TDMS data files is also possible the same way.

BOLAB WaveMaster Software allows generating analog signals for the power supplies and 4 quadrant amplifiers as well as for recording data for both voltage and current measurements to produce these synchronous and live in parallel to the reference waveform.

Data generation and data acquisition were never that easy.

Easy to use – magic in its functionality!

BOLAB WaveMaster Software Remote DLLs

With the BOLAB WaveMaster Software, remote DLLs are available for nearly all programming languages. With its command library, users can control the 4-quadrant amplifiers and power supplies perfectly. There is no need to handle hardware interfaces such as USB or LAN.

One command for each function handles all interfaces. Data files are sent to the instrument within milliseconds. No need to be concerned about memory space and resolution of the amplifiers and power supplies.

A simple “load” command calculates the best possible resolution for the waveform and sends data to the arbitrary unit. In every DLL (LabView- TM, Vector CANoe, C#, C++, ANSI C, Python, etc.), all commands are identical. This allows switching between programming languages very convenient.

Commands for creating waveforms from user programming surroundings are included as well. Variable waveforms for simulation of timely ramp increases, variation of frequency, and many other applications are typical test scenarios.

Tabular and Graphic Inputs

Individual waveforms are easily generated in tabular and/or graphical spreadsheets. Sine, triangle, rectangle, and other possibilities allow user-defined waveforms generation instantly.

Copy/paste functions, both inside the BOLAB WaveMaster Software as well as data exchanges from/to EXCEL, allow for endless possibilities.

Hundreds of thousands of baselines can be maintained!

WYSIWYG (What you see is what you get)

These waveforms are shown in their real-time and amplitude ratio. The display portrays an accurate rendition of the waveforms.

If changes are implemented in the waveform, the graphic display is instantly updated and shown with actual dimensions.

Database library for standards

An existing large and constantly growing database library exists. Each waveform has its own file. At any time, files can be copied to other places. Individual database structures are also possible.

Permanently latest updates and new standards can be downloaded from the web.

BOLAB’s libraries are always kept up to date. Upcoming new standards do not need to be purchased since downloads will be available at no cost.

LV 124 / VW80000 2009 / 2013 / 2017 / …

YES	E-01	Long-term overvoltage
YES	E-02	Transient overvoltage
YES	E-03	Transient undervoltage
YES	E-04	Jumpstart
YES	E-05	Load dump
YES	E-06	Superimposed alternating voltage
YES	E-07	Slow decrease and increase of the supply voltage
YES	E-08	Slow decrease, a quick increase of the supply voltage
YES	E-09	Reset behavior
YES	E-10	Short interruptions
YES	E-11	Start pulses
YES	E-12	Voltage curve with electric system control
YES	E-13	Pin interruption
YES	E-15	Reverse polarity

Accordingly, GS 95024MBN LV124 standards, etc. are also available.

LV 148 / VDA 320

2013 / 2014 / …

YES	E48-01a	Long-term overvoltage
YES	E48-02	Transient overvoltage
YES	E48-03	Transient process in the lower operating range with limited function
YES	E48-04	Recuperation
YES	E48-05	Superimposed AC voltage
YES	E48-06	Slow decrease and increase of the supply voltage
YES	E48-07	Slow decrease, a quick increase of the supply voltage
YES	E48-08	Reset behavior
YES	E48-09	Short interruptions
YES	E48-10	Start pulses
YES	E48-15	Operation in the range without functional limitation
YES	E48-16	Operation in the upper range with functional limitation
YES	E48-17	Operation in the lower range with functional limitation
YES	E48-18	Overvoltage range
YES	E48-19	Undervoltage range

ISO 16750-2

2003 / 2006 / 2010 / 2011 / …

YES	4.3.x	Overvoltage Systems
YES	4.4.2	Superimposed altering Voltage
YES	4.5	Slow decrease and increase of supply voltage
YES	4.6	Slow decrease and increase of supply voltage
YES	4.6.2	Reset Behavior at Voltage Drop Code
YES	4.6.3	Starting Profile
YES	4.6.4	Load Dump
YES	4.7	Reversed Voltage

ISO 7637-2

2002 / 2004 / 2007 / 2011 / …

Test Pulses 2b
Test Pulses 4

Some waveforms and tests require additional hardware components. Please contact us for assistance.

LV 123 / VW80300 2014 / 2016 / …

	VW80300	LV 123
YES	EHV-01	10.4.1	Operation within the regular HV operating voltage range
YES	EHV-02	10.4.2	Operation within the HV overvoltage range
YES	EHV-03	10.4.3	Operation within the HV Undervoltage range
YES	-	10.4.4	Range of highly limited operating capability
YES	EH-04	-	Pre-Charging
YES	EHV-05	10.4.5	Generated HV voltage dynamics
YES	EHV-06	10.4.5	System HV voltage dynamics
YES	EHV-07	-	HV voltage dynamics of energy storage devices
YES	EHV-08	10.4.6	Generated HV voltage ripple
YES	EHV-09	10.4.6	System HV voltage ripple
YES	-	10.4.7	Overvoltage
YES	-	10.4.8	Undervoltage
YES	EHV-10	10.4.9	Load dump all the way to HV voltage limit
YES	EHV-10	-	Load dump with the rapid rate of change
YES	EHV-13	-	HV service life

Accordingly, GS 95024 MBN LV124, Porsche standards, etc. are also available.

JLR EMC

2010 / 2013 / …

YES	CI 210	Immunity From Continuous Power Line Disturbances
YES	CI 220	Mode Characteristics
YES	CI 230	CI 230 Immunity from Power Cycling
YES	4.6 CI 250	Continuous Disturbances
YES	CI 250	Transient Sequence
YES	CI 265	Waveform EFTBNRandom Sequence
YES	CI 265	Waveform Random Crank
YES	CI 270	Immunity to Voltage Overstress

GMW

2008 / 2014/ 2015 / …

YES	8.2.1	Jump Start
YES	8.2.2	Reverse Polarity
YES	8.2.3	Over Voltage
YES	9.2.2	Power Supply Interruptions
YES	9.2.3	Battery Voltage Dropout
YES	9.2.4	Sinusoidal Superimposed Voltage
YES	9.2.5	Pulse Superimposed Voltage
YES	9.2.17	Stop-Start Crank Waveforms
YES	9.2.18	Switched Battery Lines

Other libraries available:

Hyundai
McLaren
PSA Peugeot - Citroen
Fiat
Ford
MAN
Renault
Toyota
Etc.

If any standard is not available in our library:

We help and implement your standards and individual waveforms at no charge in only a few days! If technically feasible

Optional Expansion

LV 123 / VW 80300 Test Systems

15 KW – 200 KW systems
15A … 660 A
DC … 200 kHz
Including Load Dump tests!
Automated Tests
Prepared for future waveforms due to individual waveform design graphically and tabular
Integration via DLL´s into programming languages