A new firmware option has been created by Spectrum Instrumentation that allows the company’s high-speed M5i.33xx series of PCIe high-speed digitizers cards to perform on-board summation averaging. Averaging is a useful tool for reducing unwanted signal noise, while at the same time improving measurement resolution, dynamic range and signal-to-noise ratio (SNR). The new option enables the M5i digitizers to perform the averaging function by utilizing advanced, on-board, field-programmable gate array (FPGA) technology. The M5i series digitizers deliver real-time sampling at rates up to 6.4 GS/sec with 12-bit resolution, and they can stream all the acquired data directly over the PCIe bus at a record breaking 12.8 GB/sec. This outstanding capability is then further enhanced by the new firmware option, which permits acquired signals to be averaged at an astonishing rate of 15 million events per second. The price for the averaging option is $910.
“This new option for the M5i series makes for one of the most powerful averaging systems available today,” said Spectrum’s Director of Technology, Oliver Rovini. “The FPGA-based processing allows ultrafast averaging, even on complex and long waveforms. In fact, there’s enough processing power available to average waveforms that contain as many as 1 MSample per acquisition. The result is an averaging package that will be of interest to anybody working with high frequency signals or very narrow pulses that are low level or where signal details are being lost due to high amounts of noise. This includes applications such as mass spectrometry, lidar, radio astronomy, automation, radar, biomedicine, nuclear physics, communications, sonar and many more.”
Summation Averaging is a common, time-domain-based, processing technique that is used to reduce the random (uncorrelated) noise component of a signal, improving its signal-to-noise ratio (SNR), while at the same time increasing a digitizer’s measurement resolution and dynamic range. Figure 2 shows an example of how averaging can be used to reveal signal details that are otherwise buried by excessive noise.
Ideally, if the signal and noise are uncorrelated, i.e., the noise being random while the signal is repetitive, then the summation averaging function can improve the SNR in proportion to the square root of the number of measurements (or averages). For example, averaging a signal 256 times may improve the SNR by as much as 24 dB or increase measurement resolution by around 4 bits. As such, this technique can be used to improve and extend the 12-bit resolution of the M5i series digitizers.
To further enhance the averaging capability, and allow the M5i series digitizers to detect and average rare events that might otherwise be lost in excessive background noise, the new firmware option includes a data suppression technique called Threshold Defined Averaging (TDA). TDA allows the user to set a threshold level so that only waveform samples exceeding the level contribute to the accumulated waveform. Baseline noise samples, those that fall below the set level, are then suppressed by being set to zero, or, as an alternative, to a user-defined value. Figure 3 shows a block diagram of the FPGA functionality and Figure 4 presents a schematic of the TDA process.
As any waveform data that is below the threshold is removed from the averaged waveform, TDA can be a useful tool for rejecting low level, correlated (synchronous) noise and other waveform artifacts, such as baseline drift. These are signal anomalies that cannot be removed by a conventional summation averaging process.
Spectrum Instrumentation, 401 Hackensack Ave., 4TH FL, Hackensack, NJ, 07601-6411, (201) 562-1999, Sales@spectrum-instrumentation.com, www.spectrum-instrumentation.com
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