Prediction of worsening of heart failure using blended reference

What is claimed is: 1. A system, comprising: a signal input circuit configured to receive at least one physiological signal from a patient; a signal processor circuit, including: a memory circuit; a reference value generator circuit including: a filter circuit to transform one or more first signal portions of the received at least one physiological signal during respective one or more first time windows into respective one or more baseline statistical values; a comparator circuit to transform one or more second signal portions of the received at least one physiological signal during respective one or more second time windows into respective one or more historical extreme values; and a blending circuit to generate one or more reference values of a physiologic parameter stored in the memory circuit using the respective one or more baseline statistical values and the respective one or more historical extreme values; and a short-term value generator circuit configured to transform one or more third signal portions of the received at least one physiological signal during respective one or more third time windows into respective one or more short-term values stored in the memory circuit, the one or more third time windows shorter than the respective first and second time windows; a cardiac condition detector circuit configured to determine a cardiac condition indicator using the one or more short-term values and the one or more reference values; and an output unit, configured to generate a human-perceptible presentation of an indication of a progression over time of the cardiac condition indicator. 2. The system of claim 1 , wherein: the filter circuit is configured to produce the one or more baseline statistical values including respective statistical measures of the physiologic parameter using the respective one or more first signal portions; and the comparator circuit is configured to produce the one or more historical extreme values including respective one or more maxima or minima of the physiologic parameter using the respective one or more second signal portions. 3. The system of claim 1 , wherein the one or more first time windows are different from the respective one or more second time windows by at least one of a window start time, a window end time, or a window duration. 4. The system of claim 3 , wherein at least one of the one or more second time windows precedes the corresponding first time window in time. 5. The system of claim 3 , wherein at least one of the one or more second time windows has a longer window duration than the corresponding first time window. 6. The system of claim 1 , wherein: the signal input circuit is configured to receive the at least one physiologic signal including a heart sound (HS) signal; the filter circuit is configured to generate the one or more baseline statistical values including central tendency of S3 heart sound intensity values using one or more first signal portions of the received HS signal; and the comparator circuit is configured to generate the one or more historical extreme values including minimal S3 heart sound intensity values using one or more second signal portions of the received HS signal. 7. The system of claim 1 , wherein: the signal input circuit is configured to receive the at least one physiologic signal including an impedance (Z) signal; the filter circuit is configured to generate the one or more baseline statistical values including central tendency of Z values using one or more first signal portions of the received Z signal; and the comparator circuit is configured to generate the one or more historical extreme values including maximal Z values using one or more second signal portions of the received Z signal. 8. The system of claim 1 , wherein the reference value generator circuit is further configured to update the one or more reference values, including one or more of: update the one or more baseline statistical values using respective one or more specified portions of the received at least one physiologic signal, the one or more specified portions postdate the corresponding one or more first time windows; or update the one or more historical extreme values using respective one or more updated second time windows, the one or more updated second time windows differing from the corresponding second time windows by at least one of a window start time, a window end time, or a window duration. 9. The system of claim 1 , wherein the short-term value generator circuit is configured to generate the one or more short-term values using a statistical measure of the respective one or more third signal portions of the received at least one physiological signal. 10. The system of claim 1 , wherein the cardiac condition detector circuit is configured to determine the cardiac condition indicator using a combination of differences between the one or more short-term values and the corresponding one or more reference values, each of the differences scaled by a specified weight factor. 11. The system of claim 1 , wherein the cardiac condition detector circuit is configured to detect an onset of a cardiac condition when a cardiac condition indicator meets a first criterion, and to detect a termination of the cardiac condition when the cardiac condition indicator meets a second criterion. 12. A method, comprising: receiving at least one physiological signal sensed from a patient using a signal input circuit; transforming one or more first signal portions of the received at least one physiological signal during respective one or more first time windows into respective one or more baseline statistical values using a filter circuit in a reference value generator circuit of a signal processor circuit; transforming one or more second signal portions of the received at least one physiological signal during respective one or more second time windows into respective one or more historical extreme values using a comparator circuit in the reference value generator circuit; generating one or more reference values of a physiologic parameter stored in a memory circuit using the respective one or more baseline statistical values and the respective one or more historical extreme values using a blending circuit in the reference value generator circuit; transforming one or more third signal portions of the received at least one physiological signal during respective one or more third time windows into respective one or more short-term values stored in the memory circuit using a short-term value generator circuit of the signal processor circuit, the one or more third time windows shorter than the respective first and second time windows; determining a cardiac condition indicator using the one or more short-term values and the one or more reference values using a cardiac condition detector circuit; and generating a human-perceptible presentation of an indication of a progression over time of the cardiac condition indicator using an output unit. 13. The method of claim 12 , wherein the one or more baseline statistical values include respective statistical measures of the physiologic parameter using the respective one or more first signal portions, and the one or more historical extreme values including respective one or more maxima or minima of the physiologic parameter using the respective one or more second signal portions. 14. The method of claim 12 , wherein the one or more first time windows are different from the respective one or more second time windows by at least one of a window start time, a window end time, or a window duration. 15. The method of