Rapid Prototyping

Rapid Prototyping

Rapid Control Prototyping provides you with mechanisms for testing control algorithms quickly and efficiently without having to replace the entire ECU software. This approach can be applied with both physical and virtual ECUs.

Below you will find fundamental information on Rapid Prototyping as well as details on:


Bypassing means that parts of the control algorithm are computed outside the ECU in an additional real-time hardware component. The VN8900 family is used for these real-time hardware components.

A blue function block in which algorithm A runs is depicted in the ECU. In order to permit use of the revised version A‘ of the algorithm, the input data to algorithm A is read from the controller via XCP (DAQ). In the first step, the bypassing coordinator acquires the data and then passes it to algorithm A‘ in step 2. A‘ is executed on the bypassing hardware and the output data is passed back to the bypassing coordinator in step 3. This is then passed on to the controller via XCP (STIM) in step 4. This method is based on the XCP standard protocol and makes it possible to integrate the algorithms on the bypassing hardware with the ECU I/O and other software. An important prerequisite for this is a high-performance physical connection to the ECU like the VX1000 measurement and calibration hardware.

The model and application algorithms are checked and adapted using XCP.

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In fullpassing, the entire code is taken from the ECU and is computed on a separate hardware component. This situation occurs frequently if the ECU hardware required for the computation is not yet available. It is possible to use various platforms depending on requirements, for example in terms of real-time computation and computing performance. From a PC with virtual ECUs through to a real-time platform based on the VN8900 family. Here again, integration with XCP helps to create a vendor-independent tool chain.

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The connection between the computation hardware and ECU must offer sufficient performance in both directions in order to acquire the data, perform the computations and write the values back to the ECU. The maximum data rate is not achieved via bus interfaces such as CAN or FlexRay, but via microcontroller-specific data interfaces (JTAG, DAP, Nexus, and Aurora).

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Control Algorithm Development

The control algorithms in the ECUs are developed either by means of manual code or using a model-based approach. The two possibilities differ at the level of the development environment and the associated approach.

Development Approach

In Simulink, the algorithm is developed in a graphical modeling language, typically with function blocks taken from MathWorks or dSpace. You then generate code for a predefined platform via the MathWorks Simulink coder. With the “Vector MATLAB/Simulink MC Add-on”, you can choose “CANape” as the target platform in the Simulink coder. When you select this option, an XCP driver is integrated in the code during the generation step. After compiling and linking, you possess a DLL which you can integrate directly as a device in CANape and measure and calibrate via XCP.

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If you develop your application directly in Visual Studio then the algorithm can also be integrated as a DLL directly in CANape. Consequently, you have a Visual Studio project with your algorithm embedded in it. After compiling and linking, you possess a DLL which you can include directly as a device in CANape and which is again equipped with XCP access.

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Application Environment

Depending on the development phase, a control algorithm can be used in different environments, for example in a virtual scenario, in the laboratory, at a workstation or in the vehicle.

Vector's solutions are based on the use of standards such as XCP, A2L, CDF2.0 and MDF. As a result, you can access the same tool configurations across all the stages of development. The measurement data is always present in the same format and the files containing the parameter sets are interchangeable as required. Consequently, the time required for familiarization is extremely short and information and data can be exchanged without restriction.

Execution Platforms

Prototyping of virtual ECUs on the PC

Prototyping solutions can be used even before the ECU hardware has been developed. At the same time, the model can be computed in Simulink or as executable code (DLL) in CANape.

A connection is established from CANape to the model in Simulink via XCP on Ethernet. For this to be possible, the CANape option “Simulink XCP Server” is required. The XCP server is integrated in the model generates an A2L file of the model, creates a CANape project and starts CANape.
As a result, users possess all the measurement and calibration capabilities of CANape without requiring any further instrumentation of the model. From the measurement of signals, characteristic curves and maps through the calibration of individual parameters and the loading of complete parameter sets in the MATLAB Workspace.

Integrated S-Functions can also be measured and calibrated via XCP. You simply have to integrate these in the Simulink XCP server via the associated A2L. In this way, you access functions that, for example, have been developed by a supplier and are not available as a model.

As input values for the model, CANape accesses existing signals from measurement files and passes them to the model, with the result that no adaptations need to be made to the model in order to read the input vectors. CANape adapts fully to the time response of the model whether the model runs faster than real-time or you compute the model step-by-step.

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The compiler can be used to generate DLLs from manual code or from Simulink models and these can then be seamlessly integrated in CANape. One special feature of the DLLs is that they possess XCP interfaces that make it possible to measure data or calibrate parameters directly from the DLL. When the DLL is integrated and used, it is no different from a ECU with XCP-on-Ethernet access.

CANape supplies the input data required for the DLL directly from connected data sources such as buses and ECUs or from existing measurement files.

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The Vector Tool Platform is a system extension for PC-based Vector network interfaces:

This component improves the latency and determinism of CANoe and CANape. To make this possible, the PC-based network interfaces of the VN8900 family are logically subdivided into two areas. In one of these, the interface functions as normal. The other area provides the “Extended Real Time” (ERT) component in which predefined functions can be executed under real-time conditions.

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Products Available to Support You

Runtime environments for algorithms created using different development environments.
CANape uses the Simulink XCP Server option to connect to the model in Simulink. Via this connection, it is possible to modify parameters in the model, enter real data as stimulations in the model and acquire any required measured values from the model.
A VN8900 network interface can be used as the execution platform for MATLAB/Simulink models that are used in CANape in order to achieve better real-time response. The Vector Tool Platform makes it possible to improve properties that are important for the execution of models, such as latency and determinism.
VN8900 and Vector Tool Platform


Developers of ECUS that contain sensors are confronted with two problems:

  1. Meaningful sensor data that reflects real situations is often only available in the vehicle since the required environment is not present in the laboratory.
  2. Reproducing in-vehicle sensor data is a time and cost-intensive exercise.

For these reasons, the stimulation of ECUs – whether they are real or virtual in nature – using previously recorded sensor data is an important part of development. One way to do this is to bypass the inputs and write the data directly to the ECU’s memory via XCP. Another way is to transport the data into the controller via the sensor inputs.


Products Available to Support You

Uses the XCP interface to the model in the same way as an interface to a ECU. CANape adapts fully to the time response of the Simulink model.
Provides the XCP interface between CANape and the model. It also generates the A2L of the model and creates a CANape project at the touch of a button.

Data Fusion

Various sensors are used in parallel to improve the quality of detection of objects in the vehicle's environment. The data from multiple sensors is fused into as complete a picture as possible of the environment.

Products Available to Support You

End-to-end solution from multisensor data capture through algorithm development and on to stimulation and the rapid visual display of the results.
Prototype software framework for the rapid development of complex data fusion algorithms. Includes support for 360° solutions for autonomous driving (levels 1 to 5).



Eine wichtige Aufgabe beim Entwickeln von Steuergeräten kommt der Restbussimulation zu. Sie sorgt dafür, dass dem Steuergerät eine funktionsfähige Umgebung zur Verfügung steht, ohne die sich umfassende Tests kaum realisieren lassen. Die Herausforderung für Entwickler besteht darin, unter Berücksichtigung gegebener Randbedingungen zügig eine realitätsnahe Restbussimulation zu generieren.


Auch die Umgebungssimulation spielt eine wichtige Rolle bei der Steuergeräte-Entwicklung. Sie sorgt dafür, dass dem Steuergerät zusätzlich zu den Kommunikations-Netzwerken auch die I/O-Schnittstellen beschaltet werden. Mit dem VT System können Ein- und Ausgänge eines Steuergerätes sehr einfach angesteuert werden.

Ausführungsplattform CANoe

Eine CANoe Simulation kann auf verschiedenen Plattformen ausgeführt werden, um unterschiedliche Anforderungen bezüglich Performance, Latenz und Durchsatz abzudecken:

Im klassischen Modus wird die CANoe Simulation zusammen mit der Netzwerk-Interface-Hardware auf einem Rechner ausgeführt. Es bestehen keine besonderen Anforderung hinsichtlich Performance, Latenz oder Durchsatz.

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Im RT Modus läuft die CANoe Simulation auf getrennten Rechnern. Der GUI-Teil kann hierbei auf dem normalen Arbeitsplatzrechner ausgeführt werden. Der Simulationsteil wird auf einem dedizierten Echtzeitsystem ausgeführt. Für diesen Echtzeitteil stehen folgende Plattformen zur Verfügung:


Das VN8900 Netzwerk-Interface ist eine modular aufgebaute Interface-Hardware mit vielfältig möglichen Kanalkombinationen für CAN, LIN, FlexRay, J1708 und K-Line. Die Simulation auf einer VN8900 Hardware kann auch standalone, d.h. ohne Bedien-PC ausgeführt werden.

VT System

Mit dem VT System bauen Sie Testsysteme für den Funktionstest von Steuergeräten und Fahrzeugnetzwerken auf. CANoe ist die dazugehörige Testautomatisierungs-Software. Durch den modularen Aufbau erhalten Sie mit dem VT System Lösungen, die von einfachen Testhilfsmitteln bis zu komplexen Testsystemen reichen.

CANoe RT Rack

Das CANoe RT Rack ist ein Industrie-PC mit einem optimierten Echtzeitbetriebssystem. Damit wird die Gesamtleistung des Systems bei Bedarf einfach vergrößert und es sind kürzere Latenzzeiten und genauere Timer möglich.

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Um CANoe in ein heterogenes Umfeld, das aus spezialisierten Werkzeugen unterschiedlicher Hersteller zu integrieren, sind verschiedene Schnittstellen verfügbar.


  • MATLAB/Simulink
  • FDX
  • LabVIEW
  • XiLAPI

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Bypassing is a special form of Rapid Prototyping: In it, data is acquired from the ECU, processed outside of it and the result is then written back into the ECU. Mechanisms from the XCP protocol are used to do this (DAQ for measuring the data from the ECU and STIM for stimulating the data in the ECU).

To keep latencies as short as possible, the algorithm runs in the runtime environment on the VN8900. The highest-performance XCP connection between the VN8900 bypassing hardware and the ECU is provided by means of the VX1000 measurement and calibration hardware.

Products Available to Support You

You can perform PC-based bypassing using the XCP mechanisms DAQ/STIM in combination with CANape.
Bypassing computation with deterministic time response. The overall solution is configured and the signals and parameters are displayed in CANape. A product from the VN8900 family is used as the runtime environment.
To ensure short roundtrip times, the bypass is computed at the Vector network interface with integrated VN8900 real-time computer and measurement and stimulation access is performed using the VX1000 hardware.
Scalable measurement and calibration hardware for exceptionally short roundtrip times between the bypassing algorithm and the ECU.