An Adaptively Parameterized Algorithm Estimating Respiratory Rate from a Passive Wearable RFID Smart Garment.

Robert Ross, William M Mongan, Patrick O'Neill, Ilhaan Rasheed, Adam Fontecchio, Genevieve Dion, Kapil R Dandekar
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引用次数: 2

Abstract

Currently, wired respiratory rate sensors tether patients to a location and can potentially obscure their body from medical staff. In addition, current wired respiratory rate sensors are either inaccurate or invasive. Spurred by these deficiencies, we have developed the Bellyband, a less invasive smart garment sensor, which uses wireless, passive Radio Frequency Identification (RFID) to detect bio-signals. Though the Bellyband solves many physical problems, it creates a signal processing challenge, due to its noisy, quantized signal. Here, we present an algorithm by which to estimate respiratory rate from the Bellyband. The algorithm uses an adaptively parameterized Savitzky-Golay (SG) filter to smooth the signal. The adaptive parameterization enables the algorithm to be effective on a wide range of respiratory frequencies, even when the frequencies change sharply. Further, the algorithm is three times faster and three times more accurate than the current Bellyband respiratory rate detection algorithm and is able to run in real time. Using an off-the-shelf respiratory monitor and metronome-synchronized breathing, we gathered 25 sets of data and tested the algorithm against these trials. The algorithm's respiratory rate estimates diverged from ground truth by an average Root Mean Square Error (RMSE) of 4.1 breaths per minute (BPM) over all 25 trials. Further, preliminary results suggest that the algorithm could be made as or more accurate than widely used algorithms that detect the respiratory rate of non-ventilated patients using data from an Electrocardiogram (ECG) or Impedance Plethysmography (IP).

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一种被动可穿戴RFID智能服装呼吸频率自适应参数化估计算法。
目前,有线呼吸频率传感器将患者固定在一个位置,可能会使医护人员无法看到他们的身体。此外,目前的有线呼吸频率传感器要么不准确,要么具有侵入性。受这些缺陷的刺激,我们开发了Bellyband,这是一种侵入性较小的智能服装传感器,它使用无线无源射频识别(RFID)来检测生物信号。尽管Bellyband解决了许多物理问题,但由于其噪声大、量化的信号,它给信号处理带来了挑战。在这里,我们提出了一种算法,通过它来估计Bellyband的呼吸频率。该算法使用自适应参数化的Savitzky Golay(SG)滤波器来平滑信号。自适应参数化使该算法能够在大范围的呼吸频率上有效,即使频率急剧变化。此外,该算法比当前的Bellyband呼吸频率检测算法快三倍、准确三倍,并且能够实时运行。使用现成的呼吸监测仪和节拍器同步呼吸,我们收集了25组数据,并根据这些试验测试了算法。在所有25项试验中,该算法的呼吸频率估计值与实际情况相差4.1次呼吸/分钟(BPM)的平均均方根误差(RMSE)。此外,初步结果表明,该算法可以作为或比广泛使用的算法更准确,这些算法使用心电图(ECG)或阻抗Plethymography(IP)的数据来检测非通气患者的呼吸频率。
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