How the GaGe Digitizer was used: The GaGe digitizer was used during data acquisition to digitize high-frequency ultrasound signals. These digitized signals enabled capturing high- resolution images of arterial walls, essential for the adaptive pulse wave imaging (PWI) technique to analyze arterial properties accurately.
How the GaGe Digitizer was used: The GaGe digitizer, with its high sampling rate, was instrumental in capturing detailed echo signals from the high-frequency ultrasound array. It enabled precise measurement of the array’s performance, including bandwidth, sensitivity, and resolution. This high level of detail is essential for developing a system capable of visualizing minute structures within the breast, thereby enhancing biopsy accuracy.
Industry:
Medical/Pharmaceutical, Testing Labs & Research Centers
How the GaGe Digitizer was used: The GaGe Applied Technologies digitizer (Cs8325 model) was utilized to capture and analyze the acoustic emissions from microbubbles during the focused ultrasound treatment. This real-time data acquisition helped monitor the effectiveness of BBB opening by recording the cavitation spectrum.
How the GaGe Digitizer was used: The GaGe Digitizer was utilized to capture and process wideband signals transmitted through blood vessels. It tracked the movement of small blood regions over a long pulse train, enabling precise velocity estimation, even at very low speeds and near-perpendicular angles to the vessel.
How the GaGe Digitizer was used: The GaGe Digitizer was integrated into a custom-built femtosecond laser desorption/ablation postionization time-of-flight mass spectrometer. It recorded ion signals during the laser desorption and ionization processes. Along with custom control software, it enabled precise timing and data acquisition for high-speed imaging and molecular analysis.
Industry:
Medical/Pharmaceutical, Testing Labs & Research Centers
How the GaGe Digitizer was used: The study utilized a GaGe Applied Technologies digitizer model Cs8325 with a 50 MHz sampling rate to acquire data from the Optical Coherence Tomography (OCT) system. This digitizer played a crucial role in capturing high-resolution imaging data, which was essential for generating detailed OCT images of ovarian tissue.
How the GaGe Digitizer was used: The paper introduces a novel approach utilizing a CdTe semiconductor detector coupled with an energy-resolved photo-counting (ERPC) readout ASIC. This setup enables the extraction of DOI information through waveform analysis at the cathode of the CdTe detector. The GaGe digitizer (CSE1242) plays a crucial role in sampling and processing the cathode waveform, providing high-resolution data for analysis.
How the GaGe Digitizer was used: The GaGe Digitizer played a key role in capturing and processing temporal traces of acousto-optically modulated signals. It facilitated the acquisition of Fourier components essential for reconstructing bi-dimensional images in FT-AOI, demonstrating its role in enabling high-speed, high-resolution imaging.
Industry:
Medical/Pharmaceutical, Testing Labs & Research Centers
How the GaGe Digitizer was used: The GaGe Digitizer (likely model: CS14200, a 14-bit, 200 MS/s digitizer) was used to process cavitation signals during the focused ultrasound treatments. This involved driving the pulse-echo ultrasound transducer to acquire cavitation data, which is critical for quantifying the mechanical effects of FUS and ensuring precise and safe treatment parameters.
How the GaGe Digitizer was used: The GaGe digitizer played a crucial role in capturing and analyzing data. Signals from the Metallic Magnetic Calorimeter (MMC) detector were amplified and filtered before being sampled by the GaGe digitizer at 2 million samples per second (2MS/s) with 16-bit resolution. This high sampling rate and precision enabled accurate measurement of the gamma-ray spectrum.
