Methods and apparatus for improving CPAP patient compliance

What is claimed is: 1. A continuous positive airway pressure system (CPAP) comprising: a flow generator configured to provide a continuous flow of breathable gas at a positive airway pressure to at least one upper airway of a patient; a patient interface structured to engage with the at least one upper airway of the patient to deliver the continuous flow of breathable gas at the positive airway pressure, the continuous flow of breathable gas at the positive airway pressure to splint open the at least one upper airway; a microphone configured to detect audio in vicinity of the patient; and at least one hardware processor that is coupled to the microphone, the at least one hardware processor configured to: determine at least one physical quantity related to the patient while the patient interface is engaged with the at least one upper airway of the patient and the breathable gas is being provided thereto; determine, using the determined at least one physical quantity, a sleep state of the patient; based on the determined sleep state of the patient, activate or deactivate a voice-command mode for the CPAP system, wherein the voice command mode is for recognizing voice commands; during a time period in which the voice-command mode of the CPAP system is activated: receive signals that are indicative of speech from the patient, recognize patient speech based on the received signals, and trigger functionality of the CPAP system based on the recognized patient speech; and deactivate the voice-command mode for the CPAP system based on determination that the sleep state indicates the patient is sleeping, wherein voice commands are not used to trigger functionality of the CPAP system when the voice-command mode is deactivated, wherein the continuous flow of breathable gas at the positive airway pressure to the at least one upper airway of the patient is provided while the voice-command mode is deactivated. 2. The CPAP system of claim 1 , wherein the at least one physical quantity is detection of ventilation levels, respiratory rates, breathing patterns, rapid eye movement (REM) sleep, slow-wave sleep, and/or posture of the patient. 3. The CPAP system of claim 1 , further comprising: at least one sensor configured to detect at least one attribute of the patient that is related to an attempt by the patient to speak, wherein the at least one hardware processor is further configured to: determine, during application of the continuous positive airway pressure and based on the detected at least one attribute, when the patient is attempting to speak; and responsive to determination that the patient is attempting to speak, automatically reduce a pressure of the continuous flow of breathable gas while the flow generator continues to provide the continuous flow of breathable gas. 4. The CPAP system of claim 3 , wherein pressure supplied during the expiration phase of the respiratory cycle of the patient is changed more than the pressure supplied during inspiration of the respiratory cycle of the patient. 5. The CPAP system of claim 3 , wherein the received signals that are recognized as indicative of speech are recognized as such while the pressure of the continuous flow of breathable gas is reduced. 6. The CPAP system of claim 3 , wherein the at least one sensor is a pressure sensor, second microphone sensor, flow sensor, or a snore sensor. 7. The CPAP system of claim 3 , wherein the at least one hardware processor is further configured to: upon determination that no speech has been determined for at least a predetermined period of time, control the flow generator to increase the pressure of the continuous flow of breathable gas. 8. The CPAP system of claim 7 , wherein the pressure is increased to a level that is similar to a pressure level provided prior to the automatic reduction in pressure. 9. The CPAP system of claim 7 , wherein determination of the patient attempting to speak includes determination of a snore signal above a snore threshold and/or determination of a positive flow derivative above a flow threshold. 10. The CPAP system of claim 1 , wherein the sleep state includes an awake state of the patient or a sleeping state of the patient. 11. The CPAP system of claim 10 , wherein the sleeping state is a rapid eye movement (REM) state or a slow-wave sleep state. 12. The CPAP system of claim 1 , wherein the functionality of the CPAP system that is triggered causes airflow out of the mouth of the patient to be reduced. 13. A continuous positive airway pressure system (CPAP) comprising: a flow generator configured to provide a continuous flow of breathable gas at a positive airway pressure to at least one upper airway of a patient; a patient interface structured to engage with the at least one upper airway of the patient to deliver the continuous flow of breathable gas at the positive airway pressure, the continuous flow of breathable gas at the positive airway pressure to splint open the at least one upper airway; a microphone configured to detect audio in vicinity of the patient; and at least one hardware processor that is coupled to the microphone, the at least one hardware processor configured to: determine at least one physical quantity related to the patient while the patient interface is engaged with the at least one upper airway of the patient and the breathable gas is being provided thereto; determine, using the determined at least one physical quantity, a sleep state of the patient; based on the determined sleep state of the patient, activate or deactivate a voice-command mode for the CPAP system, wherein the voice command mode is for recognizing voice commands; during a time period in which the voice-command mode of the CPAP system is activated: receive signals that are indicative of speech from the patient, recognize patient speech based on the received signals, and trigger functionality of the CPAP system based on the recognized patient speech; and deactivate the voice-command mode for the CPAP system based on determination that the sleep state indicates the patient is sleeping, wherein voice commands are not used to trigger functionality of the CPAP system when the voice-command mode is deactivated, wherein signals that are received during inspiration by the patient are ignored while signals received during expiration are used for recognizing voice commands. 14. A continuous positive airway pressure system (CPAP) comprising: a flow generator configured to provide a continuous flow of breathable gas at a positive airway pressure to at least one upper airway of a patient; a patient interface structured to engage with the at least one upper airway of the patient to deliver the continuous flow of breathable gas at the positive airway pressure, the continuous flow of breathable gas at the positive airway pressure to splint open the at least one upper airway; a microphone configured to detect audio in vicinity of the patient; and at least one hardware processor that is coupled to the microphone the at least one hardware processor configured to: determine at least one physical quantity related to the patient while the patient interface is engaged with the at least one upper airway of the patient and the breathable gas is being provided thereto; determine, using the determined at least one physical quantity, a sleep state of the patient; based on the determined sleep state of the patient, activate or deactivate a voice-command mode for the CPAP system, wherein the voice command mode is for recognizing voice commands; during a time period in which the voice-command mode of the CPAP system is