Ultrasound research interface
An ultrasound research interface (URI) is a software tool loaded onto a diagnostic clinical ultrasound device which provides functionality beyond typical clinical modes of operation.
A normal clinical ultrasound user only has access to the ultrasound data in its final processed form, typically a B-Mode image, in DICOM format. For reasons of device usability they also have limited access to the processing parameters that can be modified.[1][2][3]
A URI allows a researcher to achieve different results by either acquiring the image at various intervals through the processing chain, or changing the processing parameters.
Typical B-mode receive processing chain
A typical digital ultrasound processing chain for B-Mode imaging may look as follows:
- Multiple analog signals are acquired from the ultrasound transducer (the transmitter/receiver applied to the patient)
- Analog signals may pass through one or more analog notch filters and a variable-gain amplifier (VCA)
- Multiple analog-to-digital converters convert the analog radio frequency (RF) signal to a digital RF signal sampled at a predetermined rate (typical ranges are from 20MHz to 160MHz) and at a predetermined number of bits (typical ranges are from 10 bits to 16 bits)
- Beamforming is applied to individual RF signals by applying time delays and summations as a function of time and transformed into a single RF signal
- The RF signal is run through one or more digital FIR or IIR filters to extract the most interesting parts of the signal given the clinical operation
- The filtered RF signal runs through an envelope detector and is log compressed into a grayscale format
Multiple signals processed in this way are lined up together and interpolated and rasterized into a readable image.
Data access
A URI may provide data access at many different stages of the processing chain, these include:
- Pre-beamformed digital RF data from individual channels
- Beamformed RF data
- Envelope detected data
- Interpolated image data
Where many diagnostic ultrasound devices have Doppler imaging modes for measuring blood flow, the URI may also provide access to Doppler related signal data, which can include:
- Demodulated (I/Q) data
- FFT spectral data
- Autocorrelated velocity color Doppler data
Tools
A URI may include many different tools for enabling the researcher to make better use of the device and the data captured, some of these tools include:
- Custom MATLAB programs for reading and processing signal and image data
- Software Development Kits (SDKs) for communicating with the URI, signal processing and other specialized modes of operation available on the URI
References
- ↑ Dickie K, Leung C, Zahiri R, Pelissier L. A flexible research interface for collecting clinical ultrasound images. SPIE Multispectral Image Acquisition. 2009 Oct;7494(02)
- ↑ Rohling R, Fung W, Lajevardi P. PUPIL: Programmable Ultrasound Platform and Interface Library. MICCAI. 2003 Nov;(2879);424-431
- ↑ Shamdasani V, Bae U, Sikdar S, Yoo YM, Karadayi K, Managuli R, Kim Y. Research interface on a programmable ultrasound scanner. Ultrasonics. 2008 Jul;48(03);159-168.
Ultrasound Research Laboratories
The following non-exhaustive list of research labs are typical candidates that would use an ultrasound research interface for conducting experiments and collecting data.