Apple Invents an Apple Watch Feature to measure Respiration Rate with Multi-Band Plethysmography
Apple's CEO was in the news lately saying that the Apple Watch helped him lose 30 pounds. In an interview with Mad Money's Jim Cramer Cook stated: "You know, the Watch has been an incredible move into health, in the wellness and fitness piece." Today the US Patent & Trademark Office published a patent application from Apple titled "Measuring Respiration Rate with Multi-Band Plethysmography," that focuses on yet another future Apple Watch feature related to health.
A photoplethysmogram (PPG) signal may be obtained from a pulse oximeter, which employs a light emitter and a light sensor to measure the perfusion of blood to the skin of a user. However, the signal may be compromised by noise due to motion artifacts. That is, movement of the body of a user may cause the skin and vasculature to expand and contract, introducing noise to the signal.
Apple's invention and solution to the problem outlined above covers a photoplethysmogram (PPG) signal that may be obtained from a pulse oximeter, which employs a light emitter and a light sensor to measure the perfusion of blood to the skin of a user. To address the presence of motion artifacts, examples of the present invention can receive light information from two light sensors situated in a line parallel to the direction of the blood pulse wave. The light information from each sensor may include the same noise signal, and thus subtracting one from the other can result in a heart rate signal where the noise has been canceled out. In some examples, a signal from one of the light sensors may be multiplied by a scaling factor before cancellation to account for response differences in each light sensor.
Further, multiple wavelengths of light may be employed. For various wavelengths, relatively long wavelengths may interrogate relatively deep blood vessels in comparison to relatively short wavelengths, which may interrogate relatively shallow blood vessels. Accordingly, for co-located emitters of different wavelengths, there may be a time delay in the pulse signal measured by each wavelength. For example, green light may interrogate relatively shallow blood vessels near the surface of the skin, and red light may interrogate relatively deep blood vessels deeper beneath the skin, and thus the pulse signal measured by the green light may be delayed in time compared to the pulse signal measured by the red light. The time delay as a function of time may vary according to the constriction and dilation of the blood vessels, which itself may vary according to the respiratory rate of a user. In this way, the light information of various wavelengths may be used to compute such a time delay as a function of time, and a respiratory rate signal may be determined accordingly.
Apple's patent FIG. 1 illustrates an Apple Watch having light sensors for determining a heart rate signal; FIG. 2 illustrates a method of computing a heart rate signal wherein noise due to motion artifacts has been canceled; FIG. 4 illustrates an electronic device having a light sensor for determining a respiratory rate signal; FIG. 5 illustrates a method of computing a physiological signal corresponding to a respiratory rate.
Apple notes that the electronic device #100 of FIG. 1 may be held in a user's hand or strapped to a user's wrist, among other possibilities.
For more of the technical details, see Apple's patent application 20170164884 here.
Patently Apple presents a detailed summary of patent applications with associated graphics for journalistic news purposes as each such patent application is revealed by the U.S. Patent & Trade Office. Readers are cautioned that the full text of any patent application should be read in its entirety for full and accurate details. About Making Comments on our Site: Patently Apple reserves the right to post, dismiss or edit any comments. Those using abusive language or negative behavior will result in being blacklisted on Disqus.