Non-invasive ventilation measurement

The invention claimed is: 1. A system configured to measure respiratory parameters during application of non-invasive respiratory therapy of a subject, the system comprising: a non-invasive respirator configured to ventilate the subject, the non-invasive respirator comprising one or more processors configured to execute computer program modules, wherein the computer program modules comprise: a timing module configured to determine transitions in breathing between inhalations and exhalations; a passive compliance module configured to determine a passive exhalation lung compliance during an exhalation, wherein the determination by the passive compliance module is based on a passive lung model, and wherein the exhalation is demarcated based on the transitions; a passive resistance module configured to determine a passive exhalation lung resistance during the exhalation, wherein the determination by the passive resistance module is based on the passive lung model; an active compliance module configured to determine an active lung compliance that reflects an active lung model, wherein the active lung compliance is determined based on the passive exhalation lung compliance and a weight factor, the weight factor based on an obtained subject breathing mode; an active resistance module configured to determine an active lung resistance that reflects the active lung model, wherein the active lung resistance is determined based on the passive exhalation lung resistance and a weight factor, the weight factor based on the obtained subject breathing mode; a flow module configured to determine an instantaneous estimated subject flow, wherein the flow module takes a presence of both (i) instantaneous known respiratory circuit leaks and (ii) instantaneous unknown respiratory circuit leaks into account to determine the instantaneous estimated subject flow; and a user interface configured to communicate to a user one or more of the determined respiratory parameters during a period of respiratory therapy. 2. The system of claim 1 , wherein the passive compliance module is further configured to determine a passive inhalation lung compliance during an inhalation, wherein the inhalation is demarcated based on the transitions, wherein the passive resistance module is further configured to determine a passive inhalation lung resistance during the inhalation, wherein the determination by the active compliance module is further based on the passive inhalation lung compliance, and wherein the determination by the active resistance module is further based on the passive inhalation lung resistance. 3. The system of claim 1 , wherein the flow module is further configured to determine a breath-by-breath subject flow based on a respiratory circuit flow, wherein the passive lung model is based on the determined breath-by-breath subject flow. 4. The system of claim 3 , wherein application of the non-invasive respiratory therapy includes a systemic leak, wherein the systemic leak includes a known circuit leak and an unknown leak at or near a leak orifice of the subject, and wherein determination by the flow module of the breath-by-breath subject flow is further based on the systemic leak. 5. The system of claim 4 , wherein the unknown leak at or near the leak orifice of the subject is based on an average resistance of the leak orifice. 6. The system of claim 5 , wherein the average resistance of the leak orifice is determined based on the transitions in breathing between inhalations and exhalations. 7. The system of claim 1 , wherein the subject breathing mode is a spontaneous breathing mode or a non-spontaneous breathing mode. 8. A method for measuring respiratory parameters during non invasive respiratory therapy of a subject, the method comprising: providing a non-invasive respirator configured to ventilate the subject via a subject breathing mode, the non-invasive respirator comprising a processor; determining, by the processor, transitions in breathing between inhalations and exhalations; determining, by the processor, a passive exhalation lung compliance, during an exhalation, based on a passive lung model, wherein the exhalation is demarcated based on the transitions; determining, by the processor, a passive exhalation lung resistance, during the exhalation, based on the passive lung model; determining, by the processor, an active lung compliance that reflects an active lung model, wherein the determination is based on the passive exhalation lung compliance and a weight factor, the weight factor based on the subject breathing mode; determining, by the processor, an active lung resistance that reflects the active lung model, wherein the determination is based on the passive exhalation lung resistance and the weight factor based on the subject breathing mode; determining, by the processor, an instantaneous estimated subject flow, wherein determining the instantaneous estimated subject flow takes a presence of both (i) instantaneous known respiratory circuit leaks and (ii) instantaneous unknown respiratory circuit leaks into account to determine the instantaneous estimated subject flow; and communicating, to a user via a user interface, one or more of the determined respiratory parameters during a period of respiratory therapy. 9. The method of claim 8 , further comprising: determining a passive inhalation lung compliance, during an inhalation, wherein the inhalation is demarcated based on the transitions; and determining a passive inhalation lung resistance, during the inhalation, wherein determining the active lung compliance is further based on the passive inhalation lung compliance, and wherein determining the active lung resistance is further based on the passive inhalation lung resistance. 10. The method of claim 8 , further comprising: obtaining a respiratory circuit flow of the non-invasive respiratory therapy of the subject; and determining a breath-by-breath subject flow based on the respiratory circuit flow, wherein the passive lung model is based on the determined breath-by-breath subject flow. 11. The method of claim 10 , wherein application of the non-invasive respiratory therapy includes a systemic leak, wherein the systemic leak includes a known circuit leak and an unknown leak at or near a leak orifice of the subject, and wherein determining the breath-by-breath subject flow is further based on the systemic leak. 12. The method of claim 11 , further comprising: determining the unknown leak at or near the leak orifice of the subject based on an average resistance of the leak orifice. 13. The method of claim 12 , further comprising: determining the average resistance of the leak orifice based on the transitions in breathing between inhalations and exhalations. 14. The method of claim 8 , wherein the subject breathing mode is a spontaneous breathing mode or a non-spontaneous breathing mode. 15. A system configured for measuring respiratory parameters during application of non-invasive respiratory therapy of a subject, the system comprising a non-invasive respirator configured to ventilate the subject using a subject breathing mode, the non-invasive respirator comprising: means for determining transitions in breathing between inhalations and exhalations; means for determining a passive exhalation lung compliance, during an exhalation, based on a passive lung model, wherein the exhalation is demarcated based on the transitions; means for determining a passive exhalation lung resistance, during the exhalation, based on the passive lung model; means for determining an active lung compliance, reflecting an active l