Respiratory system and method that monitors medication flow

We claim: 1. A respiratory device monitoring system for monitoring the use of an inhaler, the inhaler having a hollow inhaler body that is L-shaped and which includes a mouthpiece section at a first end of the inhaler body and an opening at a second end of the inhaler body with an opening diameter that is larger than an outer diameter of a canister thereby accepting a canister in the inhaler body, the canister containing an inhaler medication that is actuated by pressing a top of the canister to move the canister inwards into the inhaler body to provide a medication dose, wherein the length of the inhaler body is selected such that the canister top and a length of the canister adjoining the canister top protrude from the inhaler body opening, the inhaler body further including an internal inhaled-air passage located from the inhaler body opening and extending through the mouthpiece, wherein the inhaled-air passage is located in a space between the inhaler body and a canister mounted in the inhaler body, wherein the inhaler is configured so that both the inhaler medication and the inhaled-air passage are connected to the mouthpiece at a point of convergence whereby a user who inhales through the mouthpiece will inhale both the dose of medication from a canister and air through the inhaled-air passage, the monitoring system comprising: a tracking module comprising a flexible shell that has a shell body wrapped around the inhaler body from the mouthpiece to the inhaler body opening, the flexible shell not covering the inhaler body opening, the flexible shell having a tracking module processor to which are connected a tracking module non-transient memory, and a tracking module communications component, the flexible 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 flexible shell further includes a flap extending over the top of a canister that is mounted through the inhaler body opening, wherein the flap includes a dose sensor mounted in the flap at a position selected so that the dose sensor will be in contact with the top of the canister to sense pressure applied to the top of the canister to actuate the canister to provide a medication dose through the mouthpiece of the inhaler, the dose sensor providing a dose signal when it has sensed said actuation pressure, wherein the flap does not cover the opening of the inhaler body; wherein the tracking module processor is in communication with the dose sensor and is programmed to receive a dose signal from the dose sensor, and to store the received dose signal in the tracking module memory with an associated time/date stamp; wherein the flap further comprises an extension portion to which is mounted an air flow sensor located wherein the extension portion has a length so that the air flow sensor is located within the inhaled-air passage of the inhaler body when the flap is mounted in contact with the top of the canister, wherein the air flow sensor detects a flow of air in the inhaled-air passage when a user inhales through the inhaler 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; wherein the tracking module processor is in communication with the air flow sensor and is programmed to receive the inhaled-air data from said sensor and to store the inhaled-air data in the non-transient memory with an associated time/date stamp; and an application program stored in a local device that is in communication with the tracking module communications component of the tracking module, the application program configured to program the local device to communicate with the tracking module processor to request stored dose data with its associated time stamps and inhaled-air data with its associated time/date stamps to be transmitted to the local device, wherein the application program further programs the local device to receive the transmitted dose data and inhaled-air data with their respective associated time stamps. 2. The monitoring system of claim 1 wherein the air flow sensor is located in the inhaled-air passage upstream of the point of convergence of the inhaler medication and the inhaled air passage, the air flow sensor comprising a pressure sensor configured to provide upstream pressure data to the tracking module processor for storage in the tracking module memory with associated time/date stamps. 3. The monitoring system of claim 2 wherein the application programs the local device to receive upstream pressure data and dose data from the tracking module; and to compare length time and pressure of the upstream pressure of the inhaled air with the time of the dose data to provide inhaler technique data based on the comparison. 4. The monitoring system of claim 1 wherein the air flow sensor comprises a first air flow sensor located in the inhaled-air passage upstream of the point of convergence of the inhaler medication and the inhaled air passage, and a second air flow sensor located in the inhaled-air passage downstream of the point of convergence of the inhaler medication and the inhaled air passage; wherein the first and second air flow sensors comprise first and second pressure sensors respectively and the first pressure sensor provides upstream pressure data to the tracking module processor for storage in the tracking module memory with associated time/date stamps, and the second pressure sensor provides downstream pressure data to the tracking module processor for storage in the tracking module memory with associated time/date stamps. 5. The monitoring system of claim 4 wherein the application programs the local device to receive upstream pressure data and downstream pressure data and dose data from the tracking module; and to compare lengths of time and pressure of the upstream and downstream pressures of the inhaled air with the time of the dose data to provide inhaler technique data based on the comparison. 6. The monitoring system of claim 1 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. 7. The monitoring system of claim 1 wherein the application program programs the local device to: receive inhaled air data and dose data from the tracking module for a particular inhalation; process the received inhaled air data to provide flow rate data; and compare the flow rate of the inhalation to the dose data to determine a quality of inhalation. 8. The monitoring system of claim 7 wherein the local device includes a display; wherein the application program programs the local device to display the quality of inhalation on the display. 9. The monitoring system of claim 1 wherein the tracking module further comprises an air flow control device having an orifice of a known size, the air flow control device configured to block ambient air from flowing into the inhaled-air passage of the inhaler except through the orifice in the air flow cont