Company Filing History:
Years Active: 2019-2023
Title: Lorenz Kahl - Innovator in Medical Signal Processing
Introduction
Lorenz Kahl is a notable inventor based in Lübeck, Germany. He has made significant contributions to the field of medical technology, particularly in the area of signal processing for cardiogenic and respiratory signals. With a total of 2 patents, Kahl's work is instrumental in advancing medical devices that enhance patient care.
Latest Patents
Kahl's latest patents include a "Process and signal processing unit for determining a cardiogenic signal" and a "Method and device for generating a control signal for a ventilator." The first patent focuses on a process and unit that estimates respiratory signals by generating a sum signal that combines respiratory and cardiogenic signals. This unit detects heartbeats and calculates an intermediate signal by compensating for the influence of cardiac activity. The estimated respiratory signal is derived from mapped intermediate signal sections and an attenuation signal.
The second patent outlines a method for controlling a ventilator by recording an electromyogram signal and transforming it into an evaluation signal. This evaluation signal indicates whether the electromyogram corresponds to an inhalation or exhalation state, allowing the ventilator to switch modes accordingly.
Career Highlights
Lorenz Kahl is currently employed at Drägerwerk AG & Co. KGaA, a company renowned for its medical and safety technology. His work at Drägerwerk has allowed him to apply his innovative ideas in practical applications that benefit healthcare professionals and patients alike.
Collaborations
Kahl collaborates with Marcus Eger, a fellow innovator in the field. Their partnership enhances the development of advanced medical technologies, contributing to the overall progress in medical signal processing.
Conclusion
Lorenz Kahl's contributions to medical technology through his patents and collaborations highlight his role as a key innovator in the field. His work continues to impact the way medical devices function, ultimately improving patient outcomes.