Minimum resource requirements at maximum flexibility
Fields of use
Microcontroller-based platforms for on-board electronics of buses and trucks (body controllers and instrument clusters)
Customer benefits
Use of a customer-specific runtime system
Minimal resource and memory consumption
Built-in test manager for automated testing
Consistent programming processes in global teams through embedded collaboration tools
Flexibly extensible by our customer: Integration of customer's own hardware configuration tools
Components used from our solutions
logi.nRTS API:
With the help of the logi.nRTS API, the automation application implemented with logi.CAD 3 can be processed by a customer's own runtime system.
logi.CAD 3:
The entire logi.CAD 3 toolchain is available for programming the applications. The applications are validated by the integrated test manager, which enables continuous, automated tests.
Test manager features
Code repositories (for collaborative work)
Static code analysis
Software-in-the-loop test (SiL testing)
Processor-in-the-loop test (PiL testing)
The flexible extension options (embedding of a customer-specific hardware and signal configurator) as well as the compilation and optimization for the customer-specific target platform ensure minimal resource and memory consumption.
Our virtual PLC for the smart building of tomorrow
Fields of use
Virtual PLC for building automation, which is used in municipal buildings such as university hospitals and tunnels, among other things
Customer benefits
Cloud-based, virtualized PLC
Fully automated generation of complete automation applications via a customer-specific control system
Components used from our solutions
Runtime system logi.RTS:
The runtime system logi.RTS runs on a virtualized server and performs building control tasks. The application logic of the PLC running virtually in the cloud is connected to the IOs in the building via a control system.
logi.CAD 3:
Application development takes place via a customer-specific web portal that provides prefabricated function blocks and libraries programmed in logi.CAD 3.
The implementation enables the complete operation of a building via a virtual PLC (administration, configuration and parameterization).
Microcontroller-based platforms for automation and air conditioning (HVAC) of large buildings and other facilities (e.g. cruise ships)
Customer benefits
Use of a customer-specific runtime system
Minimal resource and memory consumption
Built-in test manager for automated testing
Consistent programming processes in global teams through integrated collaboration tools
Embedding of the controller and the logi.cals tools into a customer-owned web portal
Components used from our solutions
logi.nRTS API:
With the help of the logi.nRTS API, the automation application implemented with logi.CAD 3 can be processed by a customer's own runtime system.
logi.CAD 3:
The entire logi.CAD 3 toolchain is available for application programming. The applications are validated by the integrated test manager, which enables continuous, automated tests.
Testmanager Features
Code Repositories (for collaborative work)
Static code analysis
Software-in-the-loop test (SiL test)
Processor-in-the-loop test (PiL test)
Compilation and optimization for the customer-specific target platform ensures minimal resource and memory consumption.
Multi-language environment integrates application and safety engineering
Fields of use
Safety control systems in mechanical engineering
Customer Benefits
Optimal utilization of the available resources through the use of a safety-related runtime system with minimal footprint
Freedom of choice when using the IEC languages as FVL or LVL
Additional use of the C programming language as FVL
Safe parameterization of hardware components and of the safe application
Components used from our solutions
Runtime system logi.µSRTS:
Safe runtime system with small footprint, which allows the operation of safety-related applications up to SIL 3
logi.CAD 3:
Implementation of a safety-related application
The tool is qualified as T3 tool up to SIL 3 and allows the use of the different IEC languages either as Full Variability Language (FVL) or Limited Variability Language (LVL).
The C language can also be used as FVL.
A safe parameter editor enables functionally safe parameterization of the safe hardware and the safety-related application.
Safety engineering for safety functions up to ASIL C
Fields of use
Infineon Aurix-based control systems, which are used, among other things, to control self-driving heavy-duty trucks, tractors and forestry machinery, but also in construction cranes and large concrete pumps
Customer Benefits
Runtime systems with small footprint
Non-safe and safety engineering in a single tool
Realization of safety features up to ASIL C
Simplified development of hardware & software
Components used from our solutions
Two logi.cals runtime systems:
The logi.µRTS scheduler runs on the non-safe core, while the safe runtime system logi.µSRTS runs on the safety core.
logi.CAD 3:
Both runtime systems are programmed via logi.CAD 3. logi.µRTS also acts as a gateway between the programming tool and the safe scheduler logi.µSRTS.
Both safe and non-safe applications can be realized from one development environment.
The integrated safety toolchain supports, the development of safety functions up to ASIL C.
Due to the seamless integration of logi.CAD 3 into the existing customer system configuration tool, configurations for control programming can be adopted fully automatically.
Application and safety engineering in just one tool
Fields of use
Standardization and parameterization of drive controllers
Customer Benefits
Runtime system with small footprint
Application and safety engineering in a single tool
Fast and resource-effective programming processes
Simplified hardware & software development
Components used from our solutions
Runtime system logi.µSRTS:
Runtime system with small footprint, with which safe and non-safe applications can be operated on the same hardware.
logi.CAD 3:
With logi.CAD 3, both safe and non-safe applications can be programmed.
By integrating our programming tool logi.CAD 3 and an IEC-61131-3 block library into the existing customer engineering process, adaptations for the characteristics of a motion system (e.g. change of ramp-up behavior) can be implemented in an efficient and resource-effective way.