MVI69-PDPMV1 industrial PLC and DCS supplier

The MVI69-PDPMV1 simplifies multi-element and fpgaa-based application development with its intuitive parallel dataflow language. As processor manufacturers seek parallel multi-core architectures to improve performance, 8.5LVEVE running on these new processors provides faster test throughput, more efficient processor-intensive analysis, and more reliable real-time systems on dedicated processor cores. LabVie 8.5 also further extends the platform into embedded and industrial applications with new stateful design modules for modelling and implementing system behaviour, as well as new I/O libraries and analytics for industrial monitoring.” Engineers and scientists rely on ever-improving PC processors, operating systems, and bus technologies to enhance the performance of their measurement and control systems,”

With the adoption of next-generation processors, engineers and scientists must consider how their software can provide the potential performance gains of multi-core and fpga-based systems. Using LVIVW’s Parallel Data Streaming Language, users can easily map their applications to multi-source and FPGA architectures for data streaming, control, analysis and signal processing. Building on the automated multi-threading capabilities of earlier versions, LVIEW 8.5 measures user applications against the total number of cores available and provides enhanced thread-safe drivers and libraries to increase throughput for RF, high-speed digital I/O and mixed-signal test applications. Lab 8.5 also offers Symmetric Multi-Processing (SMP) with the Labour Real-Time Environment, which allows embedded and industrial system designers to automatically load balanced tasks across multiple cores without sacrificing determinism. With the latest version of LVIVW, users can manually assign portions of code to specific processor cores to fine-tune real-time systems, or isolate time-critical portions of code on dedicated cores.

MVI69-PDPMV1 To meet the more challenging debugging and code optimisation needs of real-time multi-core development, engineers and scientists can use the new Ni Real-Time Execution Trace Toolkit 2.0 to visualise the timing of code segments in relation to the individual threads and processing cores that execute the code. The lab’s inherent parallelism also makes it an ideal platform for developing FPGA applications. The task of programming FPGAs continues to be simplified with an enhanced FPGA Project Wizard that automates I/O configuration, IP development, and overall setup of general-purpose I/O, counter/timer, and encoder applications. Engineers and scientists can use the fpga Project Wizard to automatically generate more complex high-speed DMA data transfer code. In addition, LBVVE8.5 provides the multi-channel filtering and 530 control functions commonly required in machine automation, greatly reducing FPGA resources in high-channel counting applications. Counter/Timer and Encoder Applications. Engineers and scientists can use the fpga Project Wizard to automatically generate more complex high-speed DMA data transfer code.