Tracker module for monitoring the use of a respiratory device

What is claimed is: 1 . A monitoring system for monitoring the use of a respiratory device, the respiratory device having an inhaler body that includes a mouthpiece at a first portion of the inhaler body and an inhalation air opening at a second portion of the inhaler body through which air from outside the inhaler may be drawn into the inhaler body, the inhaler body further having an internal inhaled air passage that connects the inhalation air opening with the mouthpiece, the inhaler body further having a dry powder medication source located in the inhaler body in communication with the inhalation-air passage, the dry powder medication source containing respiratory dry powder medication that is released into the inhaled air passage when air is inhaled at the mouthpiece thereby drawing air from the inhalation air opening and through the inhaled air passage, whereby a user who inhales through the mouthpiece will inhale both air located outside the inhaler through the inhaled air passage and a dry powder medication dose from the medication source as the inhaled air passes through the inhaled air passage on its way to the mouthpiece, the monitoring system comprising: a tracking module comprising a shell that is temporarily mounted around the respiratory device inhaler body between the mouthpiece and the inhalation air opening whereby the tracking module is reusable with another inhaler, the shell having a tracking module processor to which are connected a tracking module non-transient memory, and a tracking module communications component, the shell also including a tracking module battery, wherein the battery is connected to provide electrical power to the processor, the memory, and the communications component; wherein the shell further includes a shell outer surface and a dose delivery switch accessible from the outer surface, the dose delivery switch being configured to provide a dose delivery signal when it senses pressure being applied to the dose delivery switch; wherein the tracking module processor is in communication with the dose delivery switch and is programmed to receive a dose delivery signal from the dose delivery switch, and to store dose delivery data in the tracking module memory that is based on a received dose delivery signal; wherein the shell further comprises an air flow sensor located in communication with the inhaled air passage to sense a flow of air through the inhaled air passage from the inhalation air opening through the inhaled air passage when a user inhales through the mouthpiece for a medication dose, the air flow sensor providing air flow data in response to detecting air flow drawn through the inhaled air passage when a user of the inhaler inhales; and wherein the tracking module processor is also in communication with the air flow sensor and is programmed to receive the air flow data and to store the received air flow data in the non-transient memory as medication dose delivery data. 2 . The monitoring system of claim 1 wherein the dose delivery switch responds to manual pressure from a user of the respiratory device to provide a medication dose delivery signal; and wherein the processor associates the dose delivery signal with air flow data to indicate the existence of a medication dose delivery. 3 . The monitoring system of claim 1 wherein the shell further comprises a second mouthpiece that fits over the first mouthpiece of the inhaler body; whereby inhaled air flowing through the inhaled air passage passes through both the first and second mouthpieces; and wherein the air flow sensor is located in the second mouthpiece to sense flow through the inhaled air passage. 4 . The monitoring system of claim 3 wherein the second mouthpiece operates as a spacer tube. 5 . The monitoring system of claim 1 wherein the processor applies time stamps to a dose delivery data and to air flow data. 6 . The monitoring system of claim 1 further comprising an application program stored in a local device that is in communication with the tracking module communications component, the application program configured to program the local device to communicate with the tracking module processor to request that stored dose delivery data and air flow data be transmitted to the local device, wherein the application program further programs the local device to receive the transmitted dose delivery data and air flow data. 7 . The monitoring system of claim 6 wherein the tracking module further comprises a biometric sensor configured to receive biometric data of a possible user; wherein the tracking module memory includes identification data of the inhaler to which the tracking module is mounted; wherein the tracking module processor is further programmed to receive biometric data from the biometric sensor, and transmit the received biometric data to the local device; and wherein the application running on the local device programs the local device to compare the received biometric data from the tracking module processor and compare the received biometric data to authorized user data, and depending on the comparison, indicate that the received biometric data matches an approved user of the inhaler. 8 . The monitoring system of claim 1 wherein the application program programs the local device to: receive air flow data and dose delivery data from the tracking module for a particular inhalation; process the received air flow data to provide flow rate data; and compare the flow rate of the inhalation to the dose delivery data to determine a quality of inhalation. 9 . The monitoring system of claim 8 wherein the local device is programmed to provide coaching to a user to improve inhalation technique based on the quality of inhalation determined from the data comparison. 10 . The monitoring system of claim 8 wherein the local device includes a display; wherein the application program programs the local device to display the quality of inhalation on the display. 11 . The monitoring system of claim 1 wherein the tracking module further comprises an air flow control device having an orifice of a known size; and wherein the application program programs the local device to determine the flow rate based on the time of inhalation and the known size of the orifice. 12 . The monitoring system of claim 1 wherein: the tracking module includes an accelerometer that provides acceleration data, location data, and orientation of the inhaler data; wherein the tracking module further comprises a user proximity sensor that senses the proximity of a user to the inhaler and provides user proximity data; the application programs the local device to receive dose delivery data, air flow data, environmental data, and medication use data, and store said received data as associated with a user's inhalation; and the application programs the local device to determine a quality of inhalation based on a comparison of the dose data and air flow data. 13 . The monitoring system of claim 12 wherein: environmental data includes at least one of temperature, humidity, allergens, pollution, and air particulates; and medication use data includes at least one of asthma treatment pills, injector pen use, and other medication use. 14 . The monitoring system of claim 1 wherein the application program programs the local device to operate in a training mode where dose delivery data and air flow data received from the tracking module are compared to provide advice to a user to change inhalation technique. 15 . The monitoring system of claim 1 wherein the tracking module comprises an accelerome