Investigation of resolution and microphone size for measurements of airborne ultrasound.

The growth of ultrasound technologies has entailed the presence of airborne ultrasound emissions in industry and public and private spaces. For occupational safety and health, procedural and technical recommendations are needed that allow measurements to be performed in the field within a short time and with little effort. This study aims to answer two research questions concerning the minimum spatial resolution and microphone size required to determine a spatial distribution of sound pressure levels with sufficient accuracy within a given measurement uncertainty.

Development of a Personal Ultrasound Exposimeter for Occupational Health Monitoring.

Prolonged exposure to airborne ultrasound in a workplace can have a detrimental influence on a worker's well-being. Given the ever-increasing use of ultrasonic industrial equipment, it is of vital importance-and may also be regulated by law-to monitor ultrasound exposure during a normal workday as part of workplace risk assessment. However, the devices currently utilized exhibit limitations with regard to both their operational frequency and their portability (wearability).

Development of an ultrasound level meter for use in occupational safety and health.

The widespread use of ultrasound techniques throughout industry causes many workers to be exposed to airborne ultrasound at their workplaces. To measure and assess the exposure to airborne ultrasound at these workplaces, devices are required that allow reliable measurements of ultrasound levels and support occupational safety and health measures. However, the sound level meters available to date do not meet these requirements.

Experimental characterization of high-intensity focused airborne ultrasound fields.

High-intensity focused airborne ultrasound fields are increasingly applied in various technical fields, for example, to generate haptic feedback during gesture interaction. Reliable measurement data of sound pressure levels are required to assess potential health hazards to users. Such ultrasound fields pose special challenges for a quantitative characterization.