NeFaH

Digital treatment of ADHD at home. In numerous studies, the digital treatment of ADHD at home has proven to be effective in the short term and, above all, in the long term after the end of therapy. Unfortunately, however, this approach has so far been far too technically complex to be used effectively by those affected themselves or by less intensively trained staff.
The aim of the NeFaH project was to develop a new type of medical technology system for
home use, which for the first time enables comprehensive care in structurally weak regions.
for the first time.
  • Flexible and individualized therapy plan feasible
  • Effective, cost-effective, sustainable therapy with few side effects
  • High therapy compliance for ADHD in children and adults
We have developed a functional demonstrator of a neurofeedback device (NeFaH box for home use).

5G Kompass

As part of our latest project, we have developed a heterogeneous indoor radio access network (i-RAN) based on newly and further developed LAN and WLAN components. This advanced network integrates both the 5G core network and the traditional 5G Radio Access Network (RAN) to ensure seamless and efficient connectivity in industrial environments.

The use of open interfaces and the integration of artificial intelligence (AI) and machine learning (ML) enables a high quality of service in the Industrial Internet of Things (IIoT). Our i-RAN system is specifically designed to meet the growing demands of Industry 4.0 by providing a reliable and flexible communication infrastructure that adapts to the dynamic requirements of industrial applications.

POF-ALL

The aim of the POF-All project (“Paving the Optical Future with Affordable Lightning-fast Links”) was to develop a transmission technology that makes it possible to transmit data rates of 100+ Mbit/s symmetrically over distances that allow telecommunications subscribers to be connected in buildings. By using plastic optical fibers (POF), this can lead to significantly lower costs than is currently the case with existing alternative solutions. Based on its own proposed solution, Teleconnect worked on the development of a hardware solution for transmitter and receiver modules. Further information can be found at www.ist-pof-all.org.  The project is funded by the EU, FP6-IST STREP “POF-ALL”, contract no.: 027549

System on Chip

As part of an application for the IP2 project, we worked on innovative EDA methods (Electronic Design Automation) and products for future generations of mobile radio systems. The content of our work included research into novel application-specific CAE methods, such as adapted intellectual property (IP x) principles and architecture-accurate prototyping, as well as their productive utilization in the development and optimization of novel configurable systems on chip (SoC). These are to be used in future Internet Protocol (IP)-based mobile networks (“The Internet is going mobile.”).

Design flow manager for IP-based SoC designs

Together with the partner “Technische Universität Dresden, Institut für Verkehrsinformationssysteme, Professur Informationstechnik für Verkehrssysteme” a system for the reuse of IP (Intelligent Properties) for System on Chip (SoC) designs was developed and prototypically realized. The system was realized on the basis of an SQL database and design flow tools integrated into a web interface after the establishment of corresponding concepts for the reuse of IP cores (Design by Reuse) and the reusability of designs (Design for Reuse). The project was funded by the European Regional Development Fund (ERDF) 2000-2006 and the Free State of Saxony.

SDL Toolsuite

Together with Zesium mobile GmbH , Teleconnect has developed a project for generating code from SDL charts. The tool suite includes a code generator that generates optimized C source code from SDL sources. This generator supports a subset of SDL - precisely the part that is needed to implement telecommunication charts. This meant that the scope of the code could be kept so lean that it can also be used for mobile communication devices. One conceivable application would be the implementation of the UMTS stack from SDL in C. A further component of the SDL suite is a test environment with which the code generated from SDL can be tested directly. This tester was developed by Teleconnect and interprets graphically created test sequences in MSC. The information required to define tests in MSC is prepared from the output of the code generator so that process and signal names can be copied and pasted directly into MSC. The tester generates an interpreter code from the MSC source, which is used to control the application directly. Messages can be forked off, inserted and displayed as a copy, breakpoints can be defined and fully automated complete tests are also possible. The project was funded as part of the program “INNOvationskompetenz mittelständischer