Dual-altitude-based non-invasive blood pressure monitoring

What is claimed is: 1 . A system for non-invasive measurement of blood pressure of a user, the system comprising: a sensor head comprising: an illumination subsystem to project illumination through a body part that includes at least one elastic blood circulatory pathway through which flows a continuously changing volume of blood; and an optical detection subsystem to generate a detection output signal based on detecting changing amounts of received portions of the illumination passing through the body part corresponding to the continuously changing volume of blood; and a control processor to generate a blood pressure measurement (BPM) output by: in a first measurement time window with the body part held positioned at a first altitude relative to the user's heart, directing the illumination subsystem to project the illumination through the body part, directing the optical detection subsystem to generate the detection output signal, and computing a first mean intensity of the detection output signal over the first measurement time window; in a second measurement time window with the body part held positioned at a second altitude relative to the user's heart, directing the illumination subsystem to project the illumination through the body part, directing the optical detection subsystem to generate the detection output signal, and computing a second mean intensity of the detection output signal over the second measurement time window; and computing the BPM output to indicate a slope-calibrated mean BPM as a function of the first mean intensity, the second mean intensity, and a slope-calibration factor, wherein the optical detection subsystem comprises a plurality of photodetectors to detect the received portions of the illumination passing through the body part, at least a first photodetector of the plurality of photodetectors configured to output an illumination stability signal indicating a quality of the received portions of the illumination, and at least a second photodetector of the plurality of photodetectors configured to output an illumination gradient signal indicating an intensity of the received portions of the illumination; and the optical detection subsystem is to generate the detection output signal based on illumination gradient signal as normalized by the illumination stability signal. 2 . The system of claim 1 , wherein the control processor is to generate the BPM output to include a simulated systolic BPM by: in the first measurement time window, further computing a first pulse to mean (PTM) ratio as a ratio between an intensity amplitude of the detection output signal in the first measurement time window and the first mean intensity; in a third measurement time window, subsequent to the first measurement time window, repeatedly computing and monitoring a decreasing PTM ratio while an altitude of the body part slowly decreases from the first altitude, based on monitoring changing values of the intensity amplitude and the mean intensity of the detection output signal resulting from the body part decreasing in altitude, until the decreasing PTM ratio reaches a second PTM ratio that is at or below a predetermined systolic threshold percentage of the first PTM ratio, such that the second PTM is computed when the body part reaches a third altitude at which the detection output signal has a third mean intensity; and computing the simulated systolic BPM as a function of the first mean intensity, the third mean intensity, and the slope-calibration factor. 3 . The system of claim 2 , wherein the control processor is to generate the BPM output to include a simulated diastolic BPM by: in a fourth measurement time window subsequent to at least the third measurement time window, repeatedly computing and monitoring an increasing PTM ratio while the altitude of the body part slowly increases from at least the third altitude, based on monitoring changing values of the intensity amplitude and the mean intensity of the detection output signal resulting from the body part increasing in altitude, until the increasing PTM ratio reaches a third PTM ratio that is at or above a predetermined diastolic threshold percentage of the first PTM ratio, such that the third PTM is computed when the body part reaches a fourth altitude at which the detection output signal has a fourth mean intensity; and computing the simulated diastolic BPM as a function of the first mean intensity, the fourth mean intensity, and the slope-calibration factor. 4 . The system of claim 1 , further comprising: an altitude sensor to output the first altitude in the first measurement time window and to output the second altitude in the second measurement time window. 5 . The system of claim 1 , wherein the slope-calibration factor includes an altitude difference factor computed by the control processor during a calibration routine, prior to the generating the BPM output, by applying a predetermined gravitational factor to a measured difference between the first altitude and the second altitude. 6 . The system of claim 1 , wherein the control processor is further to compute the slope-calibration factor during a calibration routine, prior to the generating the BPM output, by: in a first calibration time window with the body part held positioned at a first calibration altitude relative to the user's heart, directing the illumination subsystem to project the illumination through the body part, directing the optical detection subsystem to generate the detection output signal, and computing a first calibration mean intensity of the detection output signal over the first calibration time window; in a second calibration time window with the body part held positioned at a second calibration altitude relative to the user's heart, directing the illumination subsystem to project the illumination through the body part, directing the optical detection subsystem to generate the detection output signal, and computing a second calibration mean intensity of the detection output signal over the second calibration time window; computing a signal difference between the first calibration mean and the second calibration mean; obtaining an altitude difference between the first calibration altitude and the second calibration altitude; and computing the slope calibration as a product of a predetermined wearing position factor and a ratio of the altitude difference to the signal difference. 7 . The system of claim 1 , further comprising: a wearable housing comprising a contact force subsystem configured to maintain a stable contact force between the sensor head and the body part during at least the first and second measurement time windows. 8 . The system of claim 7 , wherein: the contact force subsystem comprises: a force generator to controllably produce the contact force between the sensor head and the body part; and a force monitor to output a monitoring signal indicating a present magnitude of the contact force being produced by the force generator; and the control processor is further coupled with the contact force subsystem to control the force generator responsive to the monitoring signal to maintain the stable contact force between the sensor head and the body part during at least the first and second measurement time windows. 9 . The system of claim 1 , further comprising: a wearable housing configured to position the sensor head at the body part, the body part being a forearm, wrist, or finger of the user, so that bending and extending the user's elbow transitions the sensor head between the first altitude and the second altitude. 10 . The system of claim 1 , wherein: each photodetector of the plurality of photodetectors is