Powering Point-of-Care Ultrasound in Acute Care Settings

Ultrasound, being a non-invasive diagnostic method, is widely utilized in the field of medical imaging. According to research published in the Journal of Radiology Nursing Point-of-care ultrasound (POCUS) is being seen as a “global grassroots movement” and some of the top domains for POCUS are in acute care settings, such as emergency medicine, trauma or critical care. Especially in these care settings, it is even more necessary that these ultrasound units work reliably.

Advanced Energy power supplies are designed to provide a steady, reliable power source – regardless of the specific cooling mechanism of the power supply, whether fan or convection or conduction cooling. These power supplies ensure that ultrasound devices operate at their peak performance levels, delivering consistently accurate results. Moreover, although ultrasound is a very well established and widely used diagnostic tool, there is still a lot of research and development activity taking place in the imaging postprocessing software. There is also a lot of evolution and progress on the hardware engineering side of the overall system as well as in the transducer area

At the same time, there is another trend emerging to support the increasing desire for improved image quality by further regulating EMI with additional filtering and / or switching frequency adaptations – either by synchronization or spreading spectrum. 
   
However, the growing demand for portability also poses challenges for the compactness of all components, including the power supply, the battery charging boards, the additional filtering, and any other electronic parts needed for the frequency adjustments.

Ultrasound Power Requirements

There are multiple ultrasound systems on the market for different applications and market segments. Power requirements also differ, ranging from 200 W for a very basic ultrasound unit to up to more than 1 kW for a dedicated high-end unit for computing power applications like elastography or height adjustable monitors and printers.

Most ultrasound systems use a single output power supply between 600 and 1,000 W, usually enclosed. If battery charging and discharging are used for the ultrasound system, there are different ways to incorporate them. One option is to install the battery together with the PSU and have a dedicated part for the charging and management functionality built in. Another option is to have the battery connected separately to the PSU, which still has the charging and management functionality. Both ways have their advantages and disadvantages. Having the batteries together with the PSU enclosed offers a very compact, tidy and safe approach. On the downside, the size of the battery is fixed. Whereas having the battery separated might enable an easier service-aspect (for battery replacement) as well as potential cost savings.

Most ultrasound manufacturers prefer a fan-less power supply for their higher-end units to minimize the acoustic noise for the end-user as much as possible. Internally, most of the systems are running on a 12 or a 24 Vdc bus. The bus systems have also become more varied and, next to I²C, SPI and ethernet are now becoming more common as well.

Conclusion

Ultrasound – although it has been around for more than 80 years – is one of the most widely used diagnostic modalities and still offers a lot of research and development opportunities, both in software and hardware.

The power supply is a crucial component of the ultrasound system, which requires not only reliability in delivering the right power at the required output parameters, but its quality has a direct effect on the image quality. The right power supply design ensures that ultrasound systems support the sonographer in doing their job.