Electronic smoking device with self-heating compensation

The invention claimed is: 1. An electronic smoking device comprising: an airflow sensor configured and arranged to sense airflow through the electronic smoking device and output a first signal indicative of the sensed airflow; a temperature sensor configured and arranged to sense a temperature and output a second signal indicative of the sensed temperature; and control electronics communicatively coupled to the airflow sensor and the temperature sensor, the control electronics configured and arranged to receive the first and second signals, based on the received second signal, compensate for a temperature-induced airflow sensor signal error of the first signal, and operate the electronic smoking device based on the compensated first signal, which is indicative of the true airflow through the electronic smoking device; wherein the control electronics are further configured and arranged to compensate for the temperature-induced, base-line signal error of the first signal using the following equation: Compensated First Signal=(Actual First Signal)*((1−Calibration Coefficient)*( T Airflow Sensor −T Ambient ))−Ambient Coefficient*| T Ambient −T Calibration |, where T Ambient , T Calibration , Calibration Coefficient, and Ambient Coefficient are known, and T Airflow sensor is determined based on the received second signal. 2. The electronic smoking device of claim 1 , further including a central passage configured and arranged to facilitate airflow through the electronic smoking device, a liquid reservoir configured and arranged to store an electronic cigarette liquid, a heating coil communicatively coupled with the control electronics and positioned within the central passage, and a wick placed in fluid communication between the liquid reservoir and the heating coil, and configured and arranged to draw the electronic cigarette liquid within the liquid reservoir to the heating coil via capillary action; and wherein the control electronics are further configured and arranged to in response to the compensated first signal being indicative of the airflow through the electronic smoking device, drive the heating coil with a current that causes the electronic cigarette liquid on the heating coil to vaporize into the airflow, and maintain a constant density of vapor per unit volume of airflow in response to a change in the volumetric flow rate by varying the current to the heating coil based on the compensated first signal. 3. The electronic smoking device of claim 1 , wherein the second signal is indicative of an ambient temperature around the electronic smoking device; the control electronics are further configured and arranged to associate the second signal from the temperature sensor with the ambient temperature when a standby time of the electronic smoking device exceeds a threshold time, and where the sensed ambient temperature is elevated, correct a base-line of the first signal to compensate for the temperature-induced, base-line signal error associated with the elevated ambient temperature. 4. An electronic smoking device comprising: an airflow sensor configured and arranged to sense airflow through the electronic smoking device and output a first signal indicative of the sensed airflow; a temperature sensor configured and arranged to sense a temperature and output a second signal indicative of the sensed temperature; and control electronics communicatively coupled to the airflow sensor and the temperature sensor, the control electronics configured and arranged to receive the first and second signals, based on the received second signal, compensate for a temperature-induced airflow sensor signal error of the first signal, and operate the electronic smoking device based on the compensated first signal, which is indicative of a true airflow through the electronic smoking device; wherein the sensed temperature of the temperature sensor is indicative of an elevated temperature of the electronic smoking device associated with operation of the electronic smoking device; the control electronics are further configured and arranged to associate the second signal from the temperature sensor with the elevated temperature of the electronic smoking device when a standby time of the electronic smoking device is less than a threshold time, and in response to the elevated temperature, correct a base-line signal of the first signal to compensate for a temperature-induced, base-line signal error associated with the elevated electronic smoking device temperature. 5. An electronic smoking device comprising: an airflow sensor configured and arranged to sense airflow through the electronic smoking device and output a first signal indicative of the sensed airflow; a temperature sensor configured and arranged to sense a temperature and output a second signal indicative of the sensed temperature; and control electronics communicatively coupled to the airflow sensor and the temperature sensor, the control electronics configured and arranged to receive the first and second signals, based on the received second signal, compensate for a temperature-induced airflow sensor signal error of the first signal, and operate the electronic smoking device based on the compensated first signal, which is indicative of a true airflow through the electronic smoking device; wherein the airflow sensor is a membrane-type mass airflow sensor including a first thin film temperature sensor printed on an upstream side of the mass airflow sensor, a second thin film temperature sensor printed on a downstream side of the mass airflow sensor, and a heater positioned between the first and the second thin film temperature sensors, the heater configured and arranged to maintain a constant mass airflow sensor temperature, the airflow sensor is configured and arranged without any airflow, to produce a temperature profile across the sensor membrane is substantially uniform, indicating no airflow across the sensor membrane, and with air flow across the sensor, to cool the first thin film temperature sensor more than the second thin film temperature sensor which is downstream of the heater, the extent of the temperature differential being indicative of the airflow velocity across the sensor membrane.