Heating furnace using self-calibration mode

The invention claimed is: 1. A heating control system comprising: an air circulation fan configurable to operate at a plurality of speeds; a heating unit operably coupled to the air circulation fan, wherein the heating unit comprises: a plurality of burners; a gas manifold comprising a first segment and a second segment within the gas manifold, wherein: gas communication is disallowed between the first segment and the second segment of the gas manifold; a first set of burners from the plurality of burners are disposed within the first segment of the gas manifold; and a second set of burners from the plurality of burners are disposed within the second segment of the gas manifold; a first gas valve configured to provide a first gas flow path from a gas supply to the first segment of the gas manifold; and a second gas valve configured to provide a second gas flow path from the gas supply to the second segment of the gas manifold, wherein: the second gas flow path is different from the first gas flow path; and the second gas flow path bypasses the first gas valve; a memory configured to store: a temperature rise threshold; and a temperature map that maps temperature rise values to speeds of the air circulation fan and heating unit configurations, wherein: each heating unit configuration identifies a set of active burners and a fire rate for the set of active burners; and a temperature rise value corresponds with a temperature difference between a supply air temperature and a return air temperature; and a microprocessor operably coupled to the air circulation fan, the heating unit, and the memory, and configured to: determine a first speed for the air circulation fan that corresponds with a temperature rise value using the temperature map; determine a first heating unit configuration based on the temperature rise value using the temperature map, wherein the first heating unit configuration identifies a set of active burners and a fire rate for the set of active burners; operate the air circulation fan at the first speed and the heating unit in the first heating unit configuration with at least one active burner from a plurality of burners, wherein less than all of the burners are active when the heating unit is in the first heating unit configuration; obtain a first supply air temperature while operating the air circulation fan at the first speed; obtain a first return air temperature while operating the air circulation fan at the first speed; determine a first temperature difference between the first supply air temperature and the first return air temperature; compare the first temperature difference to the temperature rise threshold; transition the air circulation fan from the first speed to a second speed when the first temperature difference is greater than the temperature rise threshold; obtain a second supply air temperature while operating the air circulation fan at the second speed; obtain a second return air temperature while operating the air circulation fan at the second speed; determine a second temperature difference between the second supply air temperature and the second return air temperature; compare the second temperature difference to the temperature rise threshold; and update the temperature map to map the second speed to the temperature rise value when the second temperature difference is less than the temperature rise threshold. 2. The system of claim 1 , wherein operating the heating unit in the first heating unit configuration comprises: activating the at least one active burner using the first gas valve; and deactivating at least one burner from the plurality of burners using the second gas valve. 3. The system of claim 1 , wherein: the heating unit comprises a manifold plug that separates a first segment and a second segment of the gas manifold, wherein the manifold plug disallows gas communication between the first segment and the second segment; and operating the heating unit in the first heating unit configuration comprises: activating the first set of burners; and deactivating the second set of. 4. The system of claim 1 , wherein the microprocessor is configured to determine the second speed using the first temperature difference and the temperature map. 5. The system of claim 1 , wherein the microprocessor is configured to transition the heating unit from the first heating unit configuration to a second heating unit configuration when the first temperature difference is greater than the temperature rise threshold, wherein transitioning the heating unit from the first heating unit configuration to the second heating unit configuration comprises adjusting the pressure of one of the first gas valve and the second gas valve for the active burners. 6. The system of claim 1 , wherein the microprocessor is configured to transition the heating unit from the first heating unit configuration to a second heating unit configuration when the first temperature difference is greater than the temperature rise threshold, wherein transitioning the heating unit from the first heating unit configuration to the second heating unit configuration comprises switching from the first set of active burners in the first segment of the gas manifold to the second set of active burners in the second segment of the gas manifold. 7. The system of claim 1 , wherein the microprocessor is configured to transition the heating unit from the first heating unit configuration to a second heating unit configuration when the first temperature difference is greater than the temperature rise threshold, wherein transitioning the heating unit from the first heating unit configuration to the second heating unit configuration comprises: switching from the first set of active burners in the first segment of the gas manifold to the second set of active burners in the second segment of the gas manifold; and adjusting the pressure of one of the first gas valve and the second gas valve for the active burners. 8. A heating control method comprising: determining, by a microprocessor, a first speed for an air circulation fan that corresponds with a temperature rise value using a temperature map that maps temperature rise values to speeds of the air circulation fan and heating unit configurations, wherein: each heating unit configuration identifies a set of active burners and a fire rate for the set of active burners; and a temperature rise value corresponds with a temperature difference between a supply air temperature and a return air temperature; determining, by the microprocessor, a first heating unit configuration based on the temperature rise value using the temperature map, wherein the first heating unit configuration identifies a set of active burners and a fire rate for the set of active burners; operating, by the microprocessor, the air circulation fan at the first speed and a heating unit in the first heating unit configuration with at least one active burner from a plurality of burners, wherein less than all of the burners are active when the heating unit is in the first heating unit configuration, wherein the heating unit comprises: a plurality of burners; a gas manifold comprising a first segment and a second segment within the gas manifold, wherein: gas communication is disallowed between the first segment and the second segment of the gas manifold; a first set of burners from the plurality of burners are disposed within the first segment of the gas manifold; and a second set of burners from the plurality of burners are disposed within the second segment of the gas manifold; a first gas valve configured to provide a first gas flow path from a gas supply to the first segment of the gas manifold; and