Systems and methods for monitoring heart function

What is claimed is: 1 . A body-weight sensing scale apparatus comprising: a weighing scale configured and arranged with a housing and a scale platform; user-physiologic sensors, including a first sensor and including a second sensor, configured and arranged to capture a cardiogram signal of a user from at least one foot of the user in real-time while the user is in an upright position and with said at least one foot of the user on the scale platform of the body weight sensing scale apparatus, the user-physiologic sensors including circuitry configured and arranged to detect and output an indication of at least one of noise present in the cardiogram signal and a physiologic characteristic of the user, by sensing and capturing a series of heart-signals from a user while the user stands on the scale platform at a stationary position, the series of heart-signals corresponding to the cardiogram signal based on a plurality of a heartbeats from the user; and a processor circuit configured and arranged to process the cardiogram signal and generate therefrom a noise-filtered cardiac-related signal indicative of a condition of the user's heart by filtering, from the cardiogram signal, noise that is due to user movement. 2 . The body-weight sensing scale apparatus of claim 1 , wherein the processor circuit includes circuitry configured and arranged to track changes for a cardiac condition, or indicate an abnormal cardiac condition. 3 . The body-weight sensing scale apparatus of claim 1 , wherein user-physiologic sensors are configured and arranged with an electrocardiogram (ECG) sensor that, when operative, detects an ECG signal from the user. 4 . The body-weight sensing scale apparatus of claim 1 , wherein user-physiologic sensors are configured and arranged with a photoplethysmograph sensor that, when operative, detects blood-flow pulsations of the user. 4 . The body-weight sensing scale apparatus of claim 1 , wherein the cardiogram signal is a ballistocardiogram signal and wherein noise-filtered cardiac-related signal is a noise-filtered ballistocardiogram signal. 5 . The body-weight sensing scale apparatus of claim 1 , wherein the cardiogram signal is a ballistocardiogram (BCG) signal, wherein noise-filtered cardiac-related signal is a noise-filtered ballistocardiogram signal, and wherein the processor circuit is further configured and arranged to process the cardiogram signal by executing an algorithm to process the captured BCG signal. 6 . The body-weight sensing scale apparatus of claim 1 , further including communication circuitry located within the housing and communicatively coupled with or integrated as part of the processor circuit, the communication circuitry being configured and arranged to communicate cardio-function data with an external circuit. 7 . The body-weight sensing scale apparatus of claim 1 , further including communication circuitry located within the housing and configured and arranged to communicate wirelessly with an external circuit for providing cardio-function data to indicate detection of an abnormal cardiac function. 8 . The body-weight sensing scale apparatus of claim 1 , further including communication circuitry located within the housing and configured and arranged to communicate with a display circuit for providing cardio-function data to indicate whether the noise-filtered cardiac-related signal corresponds to detection of an abnormal cardiac function. 9 . The body-weight sensing scale apparatus of claim 1 , further including communication circuitry located within the housing and configured and arranged to communicate with a local memory circuit for providing cardio-function data to indicate whether the noise-filtered cardiac-related signal corresponds to detection of an abnormal cardiac function. 10 . The body-weight sensing scale apparatus of claim 1 , further including communication circuitry located within the housing and a user-wearable circuit, located outside the housing, the communication circuitry and the user-wearable circuit being configured and arranged to communicate with one another for sharing data regarding physiological parameters of the user. 11 . The body-weight sensing scale apparatus of claim 1 , wherein the noise-filtered cardiac-related signal includes an interference-cancelled cardiogram signal indicative of a condition of the user's heart and the processor circuit is further configured to generate the interference-cancelled cardiogram signal by using an input indicative of body movement or a hemodynamic parameter and by using a timing reference from the user-physiologic sensors and a reference cardiogram signal to account for the noise interference. 12 . The body-weight sensing scale apparatus of claim 11 , wherein the noise-filtered cardiac-related signal is a ballistocardiogram signal. 13 . The body-weight sensing scale apparatus of claim 1 , wherein the user-physiologic sensors are further configured and arranged to provide an indication of body weight while the user is standing on the platform, and wherein the processor circuit is further configured and arranged to track changes for a cardiac condition or to indicate an abnormal cardiac condition, by tracking changes in the noise-filtered cardiac-related signal with changes in bodyweight of the user over time. 14 . The body-weight sensing scale apparatus of claim 13 , wherein the processor circuit is further configured and arranged to indicate a heart condition in response to an increase in bodyweight of the user with a detection of change in the noise-filtered cardiac-related signal over time. 15 . A body-weight sensing scale system comprising: a weighing scale configured and arranged with a housing and a scale platform; user-physiologic sensors, including a first sensor and including a second sensor, configured and arranged to capture a cardiogram signal of a user from at least one foot of the user in real-time while the user is in an upright position and with said at least one foot of the user on the scale platform of the body weight sensing scale apparatus, the user-physiologic sensors including circuitry configured and arranged to detect and output an indication of at least one of noise present in the BCG signal and a physiologic characteristic of the user, by sensing and capturing a series of heart-signals from a user while the user stands on the scale platform at a stationary position, the series of heart-signals corresponding to the cardiogram signal based on a plurality of a heartbeats from the user; a user-wearable circuit including with a sensor to detect and to communicate physiological data pertaining to physiology of the user while the user wears the user-wearable circuit; communication circuitry located within the housing; the user-wearable circuit and the communication circuitry being configured and arranged to communicate data, including the physiological data; and a processor circuit configured and arranged to process the cardiogram signal and generate therefrom a noise-filtered cardiac-related signal indicative of a condition of the user's heart by filtering, from the cardiogram signal, noise that is due to user movement. 16 . The body-weight sensing scale system of claim 15 , further including circuitry adapted to sense vibrations in the local environment and wherein the processor circuit is further configured and arranged to process the cardiogram signal by accounting for the vibrations. 17 . The body-weight sensing scale system of claim 15 , wherein the user-physiologic sensors are configured and a