How the GaGe Digitizer was used: The GaGe Digitizer was employed in conjunction with various geophysical surveying methods, including Global Navigation Satellite Signal (GNSS) positioning, Radio Echo Sounding (RES), and active-source seismic surveying. These techniques helped in precisely mapping the grounding zone of the Kamb Ice Stream and detecting any sedimentary deposits.
Industry:
Medical/Pharmaceutical, Testing Labs & Research Centers
How the GaGe Digitizer was used: The GaGe Digitizer was employed to digitize ultrasonic
signals received from the lens at a high sampling rate. This allowed for the detailed analysis
necessary for creating Nakagami parametric images.
How the GaGe Digitizer was used: The GaGe digitizer, operating at a 10MHz sampling rate, played a crucial role in recording waveforms during trap cycles, allowing for detailed data acquisition and analysis. It provided a significant upgrade over previous data acquisition systems, enabling the detection of multiple protons and investigation of backgrounds.
How the GaGe Digitizer was used: The GaGe digitizer was employed to collect high- resolution power consumption data from cryptographic hardware during operation. This data was critical for analyzing power side-channel leakage. The captured power traces were subjected to various statistical tests, including mutual information (MI) analysis, to assess and compare their effectiveness in detecting information leakage.
Industry:
Medical/Pharmaceutical, Testing Labs & Research Centers
How the GaGe Digitizer was used: The GaGe Digitizer, specifically the CS 14200 model, was employed to digitize and save photoacoustic signals in the experiments. These signals were crucial for rendering high-resolution images of stem cells labeled with gold nanocages.
How the GaGe Digitizer was used: The GaGe Razor Express 1604 digitizer, with its high- resolution and fast sampling rate, was integral to capturing and recording the VHF signals and X-ray bursts from lightning. The digitizer allowed for precise synchronization and high temporal accuracy in the data collection, essential for correlating VHF pulses with high-energy radiation.
How the GaGe Digitizer was used: The GaGe digitizer, a high-speed data acquisition device, was employed to enhance the resolution and accuracy of metallic magnetic calorimeters (MMCs). This digitizer was critical for sampling and converting analog signals to digital, allowing precise measurements of gamma rays. It provided the necessary flexibility with selectable input voltage ranges and variable acquisition rates, essential for optimizing the performance of the MMCs.
How the GaGe Digitizer was used: The GaGe Digitizer was employed to collect and process the power traces from the lidar system. Specifically, it was used in the hardware setup to digitize the voltage signal after it was amplified and filtered. This digitization is crucial for converting the analog signals into digital
How the GaGe Digitizer was used: The research utilized the GaGe CompuScope 14100 oscilloscope card to digitize ultrasonic signals. With a 14-bit resolution and a 100 MHz sampling rate, this digitizer enabled precise recording of the ultrasonic waves traveling through the pulp suspensions, which were later analyzed to determine phase velocity and attenuation.
How the GaGe Digitizer was used: The GaGe digitizer card was used to read out the CID camera’s data. In the experiments, the CID 4150 camera captured X-ray images, which were then processed using the 12-bit GaGe digitizer card. This allowed for the precise recording of the camera’s response to X-rays, facilitating the necessary calibrations. The digitizer’s high resolution and fast readout rate enabled the accurate and timely collection of data, which is essential for comparing the CID’s response with a standard Si(Li) detector.
