Non-invasive blood pressure monitors and methods of operating the same

The invention claimed is: 1. A method of operating a non-invasive blood pressure, NIBP, monitor to measure the blood pressure of a subject, comprising: determining a pattern of arrhythmias for the subject based on historical pulse or heart rate measurements; during each of a plurality of blood pressure measurements of the subject: predicting, based on the pattern of arrhythmias for the subject, a likelihood that the subject will experience an arrhythmia during inflation of a cuff that is placed around a limb of the subject; in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff does not satisfy a threshold: buffering a pressure signal output by a pressure sensor associated with the cuff, wherein the buffering is performed during inflation of the cuff; processing the buffered pressure signal across a plurality of heart beats of the subject to estimate an autocorrelation function of the buffered pressure signal; identifying a plurality of peaks in the autocorrelation function; determining a heart rate of the subject based on the plurality of peaks; adapting one or more frequency characteristics of a high-pass filter based on the heart rate; applying the filter to the buffered pressure signal to generate a filtered pressure signal; analyzing the filtered pressure signal to determine an inflation-based blood pressure measurement for the subject; and deflating the cuff over a first time interval without obtaining a deflation-based blood pressure measurement during the deflating; or in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff satisfies the threshold: causing inflation of the cuff; deflating the cuff over a second time interval that is longer than the first time interval, obtaining a deflation-based blood pressure measurement during the deflating, and providing the deflation-based blood pressure measurement as output. 2. The method of claim 1 , wherein the pattern of arrhythmias are further determined based on one or more past postures of the subject during acquisition of the historical pulse or heart rate measurements, and wherein the predicting is further based on a current posture of the subject. 3. The method of claim 1 , wherein the pattern of arrhythmias are further determined based on past activity levels of the subject during acquisition of the historical pulse or heart rate measurements, and wherein the predicting is further based on a current or recent activity level of the subject. 4. A non-invasive blood pressure, NIBP, monitor for measuring the blood pressure of a subject, the NIBP monitor comprising: a control unit that is configured to: determine a pattern of arrhythmias for the subject based on historical pulse or heart rate measurements of the subject; and during each of a plurality of scheduled blood pressure measurements of the subject: predict, based on the pattern of arrhythmias for the subject, a likelihood that the subject will experience an arrhythmia during inflation of a cuff that is placed around a limb of the subject; in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff does not satisfy a threshold: buffer a pressure signal output by a pressure sensor associated with the cuff, wherein the buffering is performed during inflation of the cuff; process the buffered pressure signal across a plurality of heart beats of the subject to estimate an autocorrelation function of the buffered pressure signal; identify a plurality of peaks in the autocorrelation function; determine a heart rate of the subject based on the plurality of peaks; adapt one or more frequency characteristics of a high-pass filter based on the heart rate; apply the filter to the buffered pressure signal to generate a filtered pressure signal; analyze the filtered pressure signal to determine an inflation-based blood pressure measurement for the subject; and deflate the cuff over a first time interval without obtaining a deflation-based blood pressure measurement during the deflating; or in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff satisfies the threshold: cause inflation of the cuff; deflate the cuff over a second time interval that is longer than the first time interval, obtain a deflation-based blood pressure measurement during the deflating, and provide the deflation-based blood pressure measurement as output. 5. At least one non-transitory computer-readable medium comprising instructions that, in response to execution of the instructions by one or more processors of a non-invasive blood pressure, NIBP, monitor for measuring the blood pressure of a subject, cause the one or more processors to perform the following operations: determining a pattern of arrhythmias for the subject based on historical pulse or heart rate measurements; during each of a plurality of blood pressure measurements of the subject: predicting, based on the pattern of arrhythmias for the subject, a likelihood that the subject will experience an arrhythmia during inflation of a cuff that is placed around a limb of the subject; in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff does not satisfy a threshold: buffering a pressure signal output by a pressure sensor associated with the cuff, wherein the buffering is performed during inflation of the cuff; processing the buffered pressure signal across a plurality of heart beats of the subject to estimate an autocorrelation function of the buffered pressure signal; identifying a plurality of peaks in the autocorrelation function; determining a heart rate of the subject based on the plurality of peaks; adapting one or more frequency characteristics of a high-pass filter based on the heart rate; applying the filter to the buffered pressure signal to generate a filtered pressure signal; analyzing the filtered pressure signal to determine an inflation-based blood pressure measurement for the subject; and deflating the cuff over a first time interval without obtaining a deflation-based blood pressure measurement during the deflating; or in response to a determination that the likelihood that the subject will experience an arrhythmia during inflation of the cuff satisfies the threshold: causing inflation of the cuff; deflating the cuff over a second time interval that is longer than the first time interval, obtaining a deflation-based blood pressure measurement during the deflating, and providing the deflation-based blood pressure measurement as output.